Multilayer Films, Coatings, and Microcapsules Comprising Polypeptides

ABSTRACT

Disclosed herein is a multilayer film comprising two or more layers of polyelectrolytes, wherein adjacent layers comprise oppositely charged polyelectrolytes. A first layer polyelectrolye comprises a composite polypeptide comprising one or more surface adsorption regions covalently linked to one or more functional regions forming a single polypeptide chain. The surface adsorption regions comprise one or more amino acid sequence motifs consisting of 5 to 15 amino acid residues. The one or more functional regions comprise 3 to about 250 amino acid residues.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a Continuation of U.S. Nonprovisional application Ser. No. 11/586,330, filed Oct. 25, 2006, which is a Continuation-In-Part of U.S. Nonprovisional application Ser. No. 10/652,364 filed Aug. 29, 2003, and also claims the benefit of U.S. 60/729,828 filed Oct. 25, 2005, which are incorporated by reference herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to the fabrication of ultrathin multilayered films on suitable surfaces by electrostatic layer-by-layer self assembly (“ELBL”). More specifically, the present invention relates to a method for designing polypeptides for the nanofabrication of thin films, coatings, and microcapsules by ELBL for applications in biomedicine and other fields.

2. Description of Related Art

ELBL is an established technique in which ultrathin films are assembled by alternating the adsorption of oppositely-charged polyelectrolytes. The process is based on the reversal of the surface charge of the film after the deposition of each layer. FIG. 1 shows a schematic diagram of the general ELBL process: films of oppositely charged polyions (cationic polyions 10 and anionic polyions 11) are assembled in successive layers on a negatively-charged planar surface 12; the surface charge is reversed after the deposition of each layer. This process is repeated until a film of desired thickness is formed. The physical basis of association is electrostatics—gravitation and nuclear forces play effectively no role—and the increase in entropy on release of counterions into solution. Because of the generality and relative simplicity of the process, ELBL allows for the deposition of many different types of materials onto many different types of surface. There are, therefore, a vast number of possible useful combinations of materials and surfaces. For a general discussion of ELBL, including its history, see Yuri Lvov, “Electrostatic Layer-by-Layer Assembly of Proteins and Polyions” in Protein Architecture: Interfacial Molecular Assembly and Immobilization Biotechnology, Y. Lvov & H. Möhwald eds. (New York: Marcel Dekker, 1999), pp. 125-167, which is incorporated herein by reference in its entirety.

ELBL has recently become a focus area in the field of nanotechnology because it can be used to fabricate films substantially less than 1 micron in thickness. Moreover, ELBL permits exceptional control over the film fabrication process, enabling the use of nanoscale materials and permitting nanoscale structural modifications. Because each layer has a thickness on the order of a few nanometers or less, depending on the type of material used and the specific adsorption process, multilayer assemblies of precisely repeatable thickness can be formed.

A number of synthetic polyelectrolytes have been employed in ELBL applications, including sodium poly(styrene sulfonate) (“PSS”), poly(allylamine hydrochloride) (“PAH”), poly(diallyldimethylammonium chloride) (“PDDA”), poly(acrylamide-co-diallyldimethylammonium chloride), poly(ethyleneimine) (“PEI”), poly(acrylic acid) (“PAA”), poly(anetholesulfonic acid), poly(vinyl sulfate) (“PVS”), and poly(vinylsulfonic acid). Such materials, however, are not generally useful for biomedical applications because they are antigenic or toxic.

Proteins, being polymers with side chains having ionizable groups, can be used in ELBL for various applications, including biomedical ones. Examples of proteins that have been used in ELBL include cytochrome c, hen egg white lysozyme, immunoglobulin G, myoglobin, hemoglobin, and serum albumin (ibid.). There are, however, difficulties with using proteins for this purpose. These include limited control over multilayer structure (because the surface of the protein is highly irregular and proteins will not ordinarily adsorb on a surface in a regular pattern), restrictions on pH due to the pH-dependence of protein solubility and structural stability, lack of biocompatibility when using exogenous proteins, and the cost of scaling up production if the gene has not been cloned; unless the protein were identical in a readily available source, e.g. a cow, the protein would have to be obtained from the organism in which it was intended for use, making the cost of large-scale production of the protein prohibitive.

By contrast polypeptides, which are generally smaller and less complex than proteins, constitute an excellent class of material for ELBL assembly, and polypeptide film structures formed by ELBL will be useful in a broad range of applications. The present invention provides a method for designing polypeptides for the nanofabrication of thin films, coatings, and microcapsules by ELBL. Polypeptides designed using the method of the present invention should exhibit several useful properties, including, without limitation, completely determined primary structure, minimal secondary structure in aqueous solution, monodispersity, completely controlled net charge per unit length, ability to form cross-links on demand, ability to reverse cross-link formation, ability to form more organized thin films than is possible with proteins, and relatively inexpensive large-scale production cost (assuming gene design, synthesis, cloning, and host expression in E. coli or yeast, or peptide synthesis).

Polypeptides designed using the method of the present invention have been shown useful for ELBL of thin film structures with targeted or possible applications in biomedical technology, food technology, and environmental technology. Such polypeptides could be used, for example, to fabricate artificial red blood cells, drug delivery devices, and antimicrobial films.

BRIEF SUMMARY OF THE INVENTION

Disclosed herein is a multilayer film comprising two or more layers of polyelectrolytes, wherein adjacent layers comprise oppositely charged polyelectrolytes. A first layer polyelectrolyte comprises a composite polypeptide comprising one or more surface adsorption regions covalently linked to one or more functional regions forming a single polypeptide chain, wherein the composite polypeptide and the one or more surface adsorption regions have the same polarity. The surface adsorption regions comprise one or more amino acid sequence motifs, the one or more amino acid sequence motifs consisting of 5 to 15 amino acid residues and having a magnitude of net charge per residue of greater than or equal to 0.4. The one or more functional regions comprise 3 to about 250 amino acid residues. The composite polypeptide is not a homopolymer, is at least 15 amino acids long, and has an aqueous solubility at pH 4 to 10 of greater than 50 μg/mL. Further, a second layer comprises a second layer polyelectrolyte comprising a polycationic material or a polyanionic material having a molecular weight of greater than 1,000 and at least 5 charges per molecule, and a charge opposite that of the first layer polypeptide.

A method of manufacturing a multilayer film, said film comprising a first layer and a second layer, wherein adjacent layers comprise oppositely charged polyelectrolytes, the method comprises covalently joining one or more surface adsorption regions and one or more functional regions to form a composite polypeptide, wherein the composite polypeptide and the one or more surface adsorption regions have the same polarity, and depositing the composite polypeptide onto a substrate or the second layer to form a first layer. When depositing comprises depositing the composite polypeptide onto a substrate, the method further comprises depositing the second layer polyelectrolyte onto the first layer.

The present invention also provides a novel method for identifying “sequence motifs” of a defined length and net charge at neutral pH in amino acid sequence information for use in ELBL, and recording a desired number of the motifs. The method comprises the steps of: (a) Obtaining an amino acid sequence for a peptide or a protein from a particular organism; (b) Locating a starter amino acid in the amino acid sequence; (c) Examining the starter amino acid and the following n amino acids to determine the number of charged amino acids having a polarity opposite the certain polarity; (d) If the number of the charged amino acids having a polarity opposite the certain polarity is one or more, continuing the method at step g; (e) Examining the starter amino acid and the following n amino acids to determine the number of charged amino acids having the certain polarity; (f) If the number of charged amino acids having the certain polarity is equal to or greater than x, recording the amino acid sequence motif consisting of the starter amino acid and the following n amino acids; (g) Locating another starter amino acid in the amino acid sequence; and (h) Repeating the method beginning at step c until the desired number of amino acid sequence motifs have been identified or all of the amino acids in the amino acid sequence have been used as the starter amino acid in step c; wherein x is greater than or equal to approximately one-half of n.

The present invention also provides a novel method for designing a polypeptide for use in ELBL, comprising the steps of: (a) Identifying and recording one or more amino acid sequence motifs having a net charge of a certain polarity using the steps mentioned in the preceding paragraph and (b) Joining a plurality of said recorded amino acid sequence motifs to form a polypeptide.

The present invention also provides a novel method for designing a polypeptide for use in ELBL comprising the following steps: (a) Designing de novo a plurality of amino acid sequence motifs, wherein said amino acid sequence motifs consist of n amino acids, at least x of which are positively charged and none is negatively charged, or at least x of which are negatively charged and none is positively charged, wherein x is greater than or equal to approximately one-half of n; and (b) Joining said plurality of said amino acid sequence motifs. The amino acid sequence motifs can comprise the 20 usual amino acids or non-natural amino acids, and the amino acids can be either left-handed (L-amino acids) or right handed (D-amino acids).

The present invention also provides a thin film, the film comprising a plurality of layers of polypeptides, the layers of polypeptides having alternating charges, wherein the polypeptides comprise at least one amino acid sequence motif consisting of n amino acids, at least x of which are positively charged and none is negatively charged, or at least x of which are negatively charged and none is positively charged, wherein x is greater than or equal to approximately one-half of n. The motifs in these polypeptides may be selected using either of the methods described above.

The present invention also provides a novel process for using cysteine and other sulfhydryl-containing amino acid types to “lock” and “unlock” the layers of polypeptide ELBL films. This process enables the films to remain stable at extremes of pH, giving greater control over the mechanical stability and diffusive properties of films nanofabricated from designed polypeptides and increasing their utility in a broad range of applications.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a schematic diagram of the general ELBL process.

FIG. 2 is a graph of the cumulative secondary structure propensities of the amino acid sequence motifs identified in human amino acid sequence information using the method of the present invention, compared with the distribution of structure propensities of 10⁵ random amino acid sequences.

FIG. 3( a) shows adsorption data as monitored by the quartz crystal microbalance technique (“QCM”) for a combination of amino acid sequences designed according to the present invention.

FIG. 3( b) shows a comparison of adsorption data as monitored by QCM for different combinations of amino acid sequences designed according to the present invention.

FIG. 3( c) shows a graph of adsorbed mass in nanograms versus layer number for amino acid sequences designed and fabricated according to the present invention.

FIG. 4( a) illustrates intra-layer disulfide bonds according to the cysteine locking method of the present invention.

FIG. 4( b) illustrates inter-layer disulfide bonds according to the cysteine locking method of the present invention.

FIG. 4( c) illustrates the oxidation and reduction of disulfide bonds in microcapsules fabricated from polypeptides designed according to the method of the present invention.

FIG. 5 is a schematic of the selection process of the present invention used to identify in existing amino acid sequence information amino acid sequence motifs having suitable electrostatic properties for ELBL.

FIG. 6 shows the number of non-redundant sequence motifs identified in available human amino acid sequence data.

FIG. 7 shows the ELBL adsorption of poly-L-glutamate and poly-L-lysine from an aqueous medium as a function of ionic strength.

FIG. 8 shows the adsorption of polypeptides designed according to the method of the present invention for experiments to probe the effect of disulfide bond formation.

FIG. 9 shows the percentage of material remaining during thin film disassembly at acidic pH as discussed with reference to FIG. 8.

FIG. 10 shows the percentage of material lost during the acidic pH disassembly step of an experiment involving de novo-designed polypeptides containing cysteine.

FIG. 11( a) illustrates the role of solution structure of peptides on film assembly, showing how the assembly behavior of poly-L-glutamate and poly-L-lysine depends on pH. QCM resonant frequency is plotted against adsorption layer. The average molecular mass of poly-L-glutamate was 84,600 Da, while that of poly-L-lysine was 84,000 Da. The numbers refer to pH values. E=Glu, K=Lys. The peptide concentration used for assembly was 2 mg/mL.

FIG. 11( b) illustrates the role of solution structure of peptides on film assembly, showing how the solution structure of poly-L-glutamate and poly-L-lysine depends on pH. Mean molar residue ellipticity is plotted as a function of pH. The peptide concentration was 0.05 mg/mL.

FIG. 12 shows adsorption data for polyelectrolytes of different lengths, illustrating that long polyelectrolytes adsorb better than short ones.

FIG. 13 illustrates an embodiment of a “composite” polypeptide (4) comprising two surface adsorption (1,2) regions and one functional region (3). Each surface adsorption region (1,2) comprises one or more motifs.

FIG. 14 illustrates independent preparation of the three different regions (1,2,3) of a composite polypeptide (4) by solution-phase synthesis, solid-phase synthesis, or recombinant peptide production.

FIG. 15 illustrates joining of three regions (1,2,3) of the composite peptide (4) by peptide synthesis to form a single polypeptide chain. Other approaches to joining the three regions of this example are possible.

FIG. 16 illustrates the average extent of proliferation of 3T3 fibroblasts after 3 days on coverslips with different surface coatings. PLL denotes 15 layers of poly(L-glutamic acid) (PLGA) and poly(L-lysine) (PLL). PLL/RGD denotes 10 layers of PLGA/PLL followed by 5 layers of RGD-containing peptides, and RGD denotes 15 layers of RGD-containing peptides. The coatings were prepared by layer-by-layer assembly, the terminal layer had a net positive charge in each case, uncoated coverslips were included as a control. Coated surfaces showed a greater extent of cell proliferation than uncoated surfaces, and surfaces coated with PLL/RGD showed the greatest proliferation.

FIG. 17 illustrates an embodiment of a “composite” polypeptide comprising two surface adsorption regions (120 and 130) and one functional region (110).

FIG. 18 (200) illustrate an embodiment of a “composite” polypeptide comprising two surface adsorption regions (120 and 130) and one functional region (111), attached to a surface (150).

DETAILED DESCRIPTION OF THE INVENTION Explanations of Terms

For convenience in the ensuing description, the following explanations of terms are adopted. However, these explanations are intended to be exemplary only. They are not intended to limit the terms as they are described or referred to throughout the specification. Rather, these explanations are meant to include any additional aspects and/or examples of the terms as described and claimed herein.

As used herein, “layer” means a film thickness increment, e.g., on a template for film formation, following an adsorption step. “Multilayer” means multiple (i.e., two or more) thickness increments. A “polyelectrolyte multilayer film” is a film comprising one or more thickness increments of polyelectrolytes. After deposition, the layers of a multilayer film may not remain as discrete layers. In fact, it is possible that there is significant intermingling of species, particularly at the interfaces of the thickness increments.

As used herein, “biocompatibility” means causing no adverse health effect upon ingestion, contact with the skin, or introduction to the bloodstream.

As used herein, “immune response” means the response of the human immune system to the presence of a substance in the bloodstream. An immune response can be characterized in a number of ways, for example, by an increase in the bloodstream of the number of antibodies that recognize a certain antigen. (Antibodies are proteins made by the immune system, and an antigen is an entity that generates an immune response.) The human body fights infection and inhibits reinfection by increasing the number of antibodies in the bloodstream. The specific immune response depends somewhat on the individual, though general patterns of response are the norm.

As used herein, “epitope” means the structure of a protein that is recognized by an antibody. Ordinarily an epitope will be on the surface of a protein. A “continuous epitope” is one that involves several amino acids in a row, not one that involves amino acid residues that happen to be in contact in a folded protein.

As used herein, “sequence motif” and “motif” mean a contiguous amino acid sequence of a given number of residues identified using the method of the current invention. In a preferred embodiment, the number of residues is 7.

As used herein, “amino acid sequence” and “sequence” mean any length of polypeptide chain that is at least two amino residues long.

As used herein, “residue” means an amino acid in a polymer; it is the residue of the amino acid monomer from which the polymer was formed. Polypeptide synthesis involves dehydration, that is, a single water molecule is “lost” on addition of the amino acid to a polypeptide chain.

As used herein, “designed polypeptide” means a polypeptide designed using the method of the present invention, and the terms “peptide” and “polypeptide” are used interchangeably.

As used herein, “primary structure” means the linear sequence of amino acids in a polypeptide chain, and “secondary structure” means the more or less regular types of structure stabilized by non-covalent interactions, usually hydrogen bonds—examples include α-helix, β-sheet, and β-turn.

As used herein, “amino acid” is not limited to the 20 usual naturally occurring L-α-amino acids; the term also refers to other L-amino acids, D-amino acids, and other non-natural amino acids, as the context permits.

As used herein, “non-natural amino acids” means amino acids other than the 20 naturally occurring ones.

A “peptoid,” or N-substituted glycine, means an analog of the corresponding amino acid monomer, with the same side chain as the corresponding amino acid but with the side chain appended to the nitrogen atom of the amino group rather than to the α-carbons of the residue. Consequently, the chemical linkages between monomers in a polypeptoid are not peptide bonds, which can be useful for limiting proteolytic digestion.

“Substrate” means a solid material with a suitable surface for adsorption of polyelectrolytes from aqueous solution. The surface of a substrate can have essentially any shape, for example, planar, spherical, rod-shaped, etc. A substrate surface can be regular or irregular. A substrate can be a crystal. Substrates range in size from the nanoscale to the macro-scale. Moreover, a substrate optionally comprise a collection of colloidal particles. A substrate can be made of organic material, inorganic material, bioactive material, or a combination thereof. Nonlimiting examples of substrates silicon wafers; charged colloidal particles, e.g., microparticles of CaCO₃ or of melamine formaldehyde; biological cells such as erythrocytes, hepatocytes, bacterial cells, or yeast cells; organic polymer lattices, e.g., polystyrene or styrene copolymer lattices; liposomes; organelles; and viruses. In one embodiment, a substrate is a medical device such as an artificial pacemaker, a cochlear implant, or a stent.

When a substrate is disintegrated or otherwise removed during or after film formation, it is called “a template” (for film formation). Template particles can be dissolved in appropriate solvents or removed by thermal treatment. If, for example, partially cross-linked melamine-formaldehyde template particles are used, the template can be disintegrated by mild chemical methods, e.g., in dimethylsulfoxide (DMSO), or by a change in pH value. After dissolution of the template particles, hollow multilayer shells remain which are composed of alternating polyelectrolyte layers.

A “microcapsule” is a polyelectrolyte film in the form of a hollow shell or a coating surrounding a core. The core comprises a variety of different encapsulants, for example, a protein, a drug, or a combination thereof.

“Bioactive molecule” means a molecule, macromolecule or a macromolecular assembly having a biological effect. The specific biological effect can be measured in a suitable assay for measuring the biological effect and normalizing per unit weight or per molecule of the bioactive molecule. A bioactive molecule can be encapsulated or retained behind a polypeptide film. Nonlimiting examples of a bioactive molecule are a protein, a functional fragment of a protein, a complex of proteins, an oligopeptide, an oligonucleotide, a nucleic acid, a ribosome, an active therapeutic agent, a phospholipid, a polysaccharide. As used herein, “bioactive molecule” further encompasses biologically active structures, such as, for example, a functional membrane fragment, a membrane structure, a virus, a pathogen, a cell, an aggregate of cells, and an organelle. Examples of a protein that can be encapsulated or retained within a polypeptide film are hemoglobin; enzymes, such as for example glucose oxidase, urease, lysozyme and the like; extracellular matrix proteins, such as for example fibronectin, laminin, vitronectin and collagen; and an antibody. Examples of a cell that can be encapsulated or retained within a polypeptide film is a transplanted islet cell, a eukaryotic cell, a bacterial cell, a plant cell, and a yeast.

As used herein, a soluble polypeptide has a solubility in aqueous solution at pH 7.0 of greater than 50 μg/mL. In another embodiment, a soluble polypeptide has an aqueous solubility at pH 7.0 of greater than or equal to about 1 mg/mL.

The following three-letter abbreviations are used herein for the 20 usual amino acids:

Ala = alanine Cys = Cysteine Asp = aspartic acid Glu = glutamic acid Phe = phenylalanine Gly = glycine His = Histidine Ile = isoleucine Lys = lysine Leu = leucine Met = methionine Asn = asparagine Pro = proline Gln = glutamine Arg = arginine Ser = Serine Thr = threonine Val = valine Trp = tryptophan Tyr = tyrosine

DESCRIPTION OF THE INVENTION

The present invention includes multilayer films comprising alternating layers of oppositely charged polyelectrolytes, wherein a first layer of the films comprises a designed polypeptide. “Designed polypeptide” means a polypeptide comprising one or more amino acid sequence motifs, wherein the polypeptide is at least 15 amino acids in length and the ratio of the number of charged residues of the same sign minus the number of residues of the opposite sign to the total number of residues in the polypeptide is greater than or equal to 0.4 at pH 7.0. In other words, the magnitude of the net charge per residue is greater than or equal to 0.4. In one embodiment, the ratio of the number of charged residues of the same sign minus the number of residues of the opposite sign to the total number of residues in the polypeptide is greater than or equal to 0.5 at pH 7.0. In other words, the magnitude of the net charge per residue is greater than or equal to 0.5. In one embodiment, a designed polypeptide is not a homopolymer.

In one embodiment, a polyelectrolyte comprises a polycationic material or a polyanionic material having a molecular weight of greater than 1,000 and at least 5 charges per molecule. In one embodiment, the polycationic material comprises a polyamine such as, for example, a polypeptide, polyvinyl amine, poly(aminostyrene), poly(aminoacrylate), poly (N-methyl aminoacrylate), poly (N-ethylaminoacrylate), poly(N,N-dimethyl aminoacrylate), poly(N,N-crosmarmelose diethylaminoacrylate), poly(aminomethacrylate), poly(N-methyl amino-methacrylate), poly(N,N-ethyl aminomethacrylate), poly(N,N-dimethyl aminomethacrylate), poly(N,N-diethyl aminomethacrylate), poly(ethyleneimine), poly (diallyl dimethylammonium chloride), poly(N,N,N-trimethylaminoacrylate chloride), poly(methyacrylamidopropyltrimethyl ammonium chloride), chitosan and combinations comprising one or more of the foregoing polycationic materials. In another embodiment, the polyanionic material comprises a polypeptide, a nucleic acid, alginate, carrageenan, furcellaran, pectin, xanthan, hyaluronic acid, heparin, heparan sulfate, chondroitin sulfate, dermatan sulfate, dextran sulfate, poly(meth)acrylic acid, oxidized cellulose, carboxymethyl cellulose, acidic polysaccharides, croscarmelose, synthetic polymers and copolymers containing pendant carboxyl groups, and combinations comprising one or more of the foregoing polyanionic materials.

The present invention also provides a method for designing polypeptides for the nanofabrication by ELBL of thin films, coatings, and microcapsules for applications in biomedicine and other fields. The method involves 5 primary design concerns: (1) the electrostatic properties of the polypeptides; (2) the physical structure of the polypeptides; (3) the physical stability of the films formed from the polypeptides; (4) the biocompatibility of the polypeptides and films; and (5) the bioactivity of the polypeptides and films. The first design concern, electrostatics, is perhaps the most important because it is the basis of ELBL. Without suitable charge properties, a polypeptide will not be soluble in aqueous solution and cannot be used for the ELBL nanofabrication of films. We have devised a novel process for identifying in amino acid sequence information amino acid sequence motifs having electrostatic properties suitable for ELBL.

The secondary structure of the polypeptides used for ELBL is also important, because the physical properties of the film, including its stability, will depend on how the solution structure of the peptide translates into its structure in the film. FIG. 11 illustrates how the solution structure of certain polypeptides correlates with film assembly. Panel (a) shows how the assembly behavior of poly-L-glutamate and poly-L-lysine depends on pH. It is clear that the α-helix conformation correlates with a greater extent of deposited material than the β-sheet conformation. The precise molecular interpretation of this behavior remains to be elucidated. Panel (b) shows how the solution structure of these peptides depends on pH. At pH 4.2 poly-L-glutamate is largely α-helical, as is poly-L-lysine at pH 10.5. Both polypeptides are in a largely unstructured coil-like conformation at pH 7.3.

The remaining concerns relate to the applications of the polypeptide films. In practicing the invention, more or less weight will be placed on these other concerns depending on the design requirements of a particular application.

By using the selection process of the present invention to identify in amino acid sequence information amino acid sequence motifs having suitable charge characteristics, and using the other design concerns to select particular motifs, one can design polypeptides suitable for the ELBL fabrication of nano-organized films for applications in biomedicine and other fields. Alternatively, one can use the method of the present invention to design polypeptides de novo for use in ELBL. The approach to de novo design is essentially the same as identifying motifs in existing amino acid sequence information, except that each residue in an amino acid sequence motif is selected by the practitioner rather than an entire motif being identified in the genomic or proteomic information of a specific organism. It must be emphasized that the fundamental polypeptide design principles adduced in the present invention are independent of whether the amino acids involved are the 20 usual naturally-occurring ones, non-natural amino acids, or some novel combination of these, in the case of de novo polypeptide design. Further, other L-amino acids and D-amino acids could be used.

The design concerns of the present invention are discussed in more detail below.

Electrostatics

We have devised a novel process for identifying in amino acid sequence information amino acid sequence motifs having electrostatic properties suitable for ELBL. Using this process, we have identified 88,315 non-redundant amino acid sequence motifs in human proteome data—the translation of the portion of the genome that encodes all known proteins in the human body. This information is publicly available at the National Center for Biotechnology Information's (“NCBI”) Web site: http://www.ncbi.nlm.nih.gov, among other places. Such information is constantly being updated as the human genome is further analyzed. As the amount of such information increases, the number of amino acid sequence motifs that could be identified in human sequence information by the selection process of the present invention as having suitable electrostatic properties for ELBL will also increase. The same is true for any organism. Accepted biochemical and physics principles, as well as the experimental results described below, indicate that the identified sequence motifs will be useful for the design of polypeptides for the nanofabrication of ELBL structures.

The key selection criterion is the average charge per unit length at neutral pH (pH 7, close to the pH of human blood). In addition, there are several structural preferences. First, it is preferred that each amino acid sequence motif consist of only 7 residues.

Total Number of Residues in the Motif

In one exemplary embodiment, a motif length of 7 was chosen in an effort to optimize biocompatibility, physical structure, and the number of non-redundant sequence motifs in available amino acid sequence data.

As discussed below, the magnitude of the net charge on the amino acid sequence motif per residue is greater than or equal to 0.4. In one embodiment, at least half of the amino acid residues in each sequence motif are charged, such that the magnitude of the net charge on the amino acid sequence motif per residue is greater than or equal to 0.5. Moreover, it is preferred, but not required, that all of the charged residues in each motif be of the same charge. These requirements ensure that each motif will be sufficiently soluble in aqueous solvent and have sufficient charge at neutral pH to be useful for ELBL. Because only a relatively small percentage of amino acid types are charged, as the length of a given amino acid sequence increases, the odds decrease that the sequence will have a sufficient percentage of appropriately charged amino acids for ELBL. 4 charged amino acids is the preferred minimum for a motif size of 7, because fewer than 4 charges yields substantially decreased peptide solubility and decreased control over ELBL.

Regarding biocompatibility (discussed further below), each identified sequence motif is long enough at 7 residues to constitute a continuous epitope (relevant to the possible immune response of an organism into which a designed peptide might be introduced), but not so long as to correspond substantially to residues both on the surface of a protein and in its interior; the charge requirements help to ensure that the sequence motif occurs on the surface of the folded protein; a charged residue cannot be formed in the core of a folded protein. By contrast, a very short motif could appear to the body to be a random sequence, or one not specifically “self,” and therefore elicit an immune response. Although the ideal length of a peptide for generating antibodies is a point of some dispute, most peptide antigens range in length from 12 to 16 residues. Motifs that are 9 residues or shorter can be effective antigens; peptides longer than 12 to 16 amino acids may contain multiple epitopes (Angeletti, R. H. (1999) Design of Useful Peptide Antigens, J. Biomol. Tech. 10:2-10, which is hereby incorporated by reference in its entirety). Thus, to minimize antigenicity one would prefer a motif shorter than 12 and, better yet, shorter than 9 residues.

The preferred motifs should not be too long for another reason: to minimize secondary structure formation. Secondary structure decreases control of the physical structure of the polypeptides (see below) and the films made from them. Thus, an amino acid sequence motif should contain 5 to 15 contiguous amino acids.

Furthermore, the maximum number of non-redundant motifs in the human genome is found when the number of residues in each motif is 7. FIG. 6 shows the number of non-redundant sequence motifs in available human amino acid sequence information. The greatest number of positive motifs is for a 5-residue length, while the greatest number of negative motifs is for a 7-residue length. The greatest number of positive and negative motifs is about the same for 5 and 7. Thus, a motif length of 7 residues would appear to maximize the number of non-redundant motifs.

For all of the above reasons, 7 residues is the preferred length of motif to optimize polypeptide design for ELBL. Nevertheless, it is possible that in some cases either slightly shorter or slightly longer motifs will work equally as well. For example, motifs 5 or 6 residues long may be employed, and motifs on the order of 8 to 15 residues in length could also be useful. Thus, an amino acid sequence motif is defined as having 5 to 15 amino acid residues.

Number of Charged Residues

Second, it is preferred that at least 4 positively-charged (basic) amino acids (Arg, His, or Lys) or at least 4 negatively-charged (acidic) amino acids (Glu or Asp) are present in each 7-residue motif at neutral pH. Combinations of positive and negative charges are disfavored in an effort to ensure a sufficiently high charge density at neutral pH. It is possible, however, that a motif containing both positive and negative amino acids could be useful for ELBL. For example, a slightly longer motif, say of 9 residues, could have 6 positively charged amino acids and 1 negatively charged amino acid. It is the magnitude of the net charge (i.e., the absolute value of the net charge) that is important—the overall peptide must be either sufficiently positively charged or sufficiently negatively charged at neutral pH. Preferred embodiments of the motifs, however, will contain only Glu or Asp or only Arg, His, or Lys as the charged amino acids (although other non-charged amino acids could, and ordinarily do, form part of the motifs), unless non-natural amino acids are admitted as acidic or basic amino acids.

FIG. 5 is a flow chart showing the steps involved in an exemplary selection process for identifying amino acid sequences having suitable electrostatic properties. It is assumed that only the 20 usual amino acids are involved. If searching for negatively-charged motifs, the process begins by locating an amino acid in the sequence data. This amino acid will be called the “starter amino acid” because it is the starting point for the analysis of the surrounding amino acids (i.e., it will begin the motif). Next, the starter amino acid and the following 6 residues are examined for occurrences of Arg, His, or Lys. If one or more Arg, His, or Lys is located in these 7 amino acids, the process is begun anew at another starter amino acid. If no Arg, His, or Lys is found, the 7 amino acids are examined to determine the number of occurrences of Glu and/or Asp. If there are at least 4 occurrences of Glu and/or Asp in the 7 residues, the sequence motif is cataloged. The selection process is essentially the same for positively charged amino acids, except that Glu and Asp are replaced by Arg, His, and Lys, and Arg, His, and Lys are replaced by Glu and Asp, respectively. Obviously, one could also begin the method at the beginning of the amino acid sequence (amino terminus) and proceed to the end (carboxyl terminus), or, alternatively, one could begin at a random point and work through all of the amino acids in the sequence, randomly or systematically in either direction. Moreover, one could use the method to identify motifs in sequence information containing non-natural amino acids. In such a case, one would search for non-natural acidic or basic amino acids instead of Glu and Asp, and Arg, Lys, and His, respectively.

In one embodiment, the one or more first amino acid sequence motifs consists of 5 to 15 amino acids, wherein the magnitude of the net charge on the first amino acid sequence motif per residue is greater than or equal to 0.4. In another embodiment, the one or more first amino acid sequence motifs consists of n amino acids, wherein the magnitude of the net charge in the first amino acid sequence motif at pH 7 is greater than or equal to approximately one-half of n, and wherein n is 5 to 15.

The remaining design concerns, namely, physical structure, physical stability, biocompatibility, and biofunctionality, deal primarily with the particular application for which the designed polypeptides will be used. As noted above, more or less weight will be placed on these concerns during the design process, depending on the desired peptide properties for a particular application.

Physical Structure

A design concern regarding the amino acid sequence motifs is their propensity to form secondary structures, notably α-helix or β-sheet. We have sought in several ways to control, notably minimize, secondary structure formation of designed polypeptides in an aqueous medium in order to maximize control over thin film layer formation. First, it is preferred that the sequence motifs be relatively short, because long motifs are more likely to adopt a stable three-dimensional structure in solution. Second, we place a glycine residue between each motif in preferred embodiments of the polypeptide designs. Glycine has a very low α-helix propensity and a very low P-sheet propensity, making it energetically very unfavorable for a glycine and its neighboring amino acids to form regular secondary structure in aqueous solution. Proline has similar properties in some respects and could be used as an alternative to glycine to join motifs. Third, we have sought to minimize the α-helix and β-sheet propensity of the designed polypeptides themselves by focusing on motifs for which the summed α-helix propensity is less than 7.5 and the summed P-sheet propensity is less than 8. (“Summed” propensity means the sum of the α-helix or β-sheet propensities of all amino acids in a motif.) It is possible, however, that amino acid sequences having a somewhat higher summed α-helix propensity and/or summed β-sheet propensity would be suitable for ELBL under some circumstances, as the Gly (or Pro) residues between motifs will play a key role in inhibiting stable secondary structure formation in the designed polypeptide. In fact, it may be desirable in certain applications for the propensity of a polypeptide to form secondary structure to be relatively high, as a specific design feature of thin film fabrication; the necessary electrostatic charge requirements for ELBL must still be met, as discussed above.

In order to be able to select amino acid sequences with desired secondary structure propensities, we first calculated the secondary structure propensities for all 20 amino acids using the method of Chou and Fasman (see P. Chou and G. Fasman Biochemistry 13:211 (1974), which is incorporated by reference herein in its entirety) using structural information from more than 1,800 high-resolution X-ray crystallographic structures (1,334 containing α-helices and 1,221 containing β-strands). Structures were selected from the Protein Data Bank (a publicly-accessible repository of protein structures) based on: (a) method of structure determination (X-ray diffraction); (b) resolution (better than 2.0 Å)—“resolution” in this context refers to the minimum size of a structure one can resolve, as in the Rayleigh criterion; and (c) structural diversity (less than 50% sequence identity between the protein crystallographic structures used to compute the helix and sheet propensities of the various amino acids). The rationale was to choose high resolution structures determined by the most reliable methodology and not to bias the propensity calculation by having similar structures. Next, for comparison 100,000 non-redundant random sequences were produced using a random number generator in a personal computer. We then calculated the secondary structure propensities for the 88,315 amino acid sequences identified using the selection process described in part (A)(1) above (59,385 non-redundant basic sequence motifs and 28,930 non-redundant acidic sequence motifs). The propensities for the random sequences were then compared to the propensities of the selected sequences. FIG. 2 shows the distribution of secondary structure formation propensities in these sequence motifs. The rectangle in FIG. 2 highlights the sequence motifs we have identified as least likely to form secondary structure on the basis of secondary structure propensities.

Physical Stability

Another design concern is control of the stability of the polypeptide ELBL films. Ionic bonds, hydrogen bonds, van der Waals interactions, and hydrophobic interactions provide some, albeit relatively limited, stability to ELBL films. By contrast, covalent disulfide bonds could provide exceptional structural strength. We have devised a novel process for using cysteine (or some other type of sulfhydryl-containing amino acid) to “lock” and “unlock” adjacent layers of polypeptide ELBL film. This process enables a polypeptide nanofabricated film to remain stable at extremes of pH, giving greater control over its mechanical stability and diffusive properties (for discussions of porosity of multilayer films made of non-polypeptide polyelectrolytes, see Caruso, F., Niikura, K., Furlong, N. and Okahata (1997) Langmuir 13:3427 and Caruso, F., Furlong, N., Ariga, K., Ichinose, I., and Kunitake, T. (1998) Langmuir 14:4559, both of which are incorporated herein by reference in their entireties). Also, the incorporation of cysteine (or some other type of sulfhydryl-containing amino acid) in a sequence motif of a designed polypeptide enables the use of relatively short peptides in thin film fabrication, by virtue of intermolecular disulfide bond formation. Without cysteine, such peptides would not generally yield sufficiently stable films (see FIG. 12, discussed below). Thus, our novel use of cysteine will obviate the need to produce expensive long versions of the designed polypeptides in a substantial percentage of possible applications. This will be particularly advantageous in situations where the thin film is to be fabricated over material to be encapsulated, for example a small crystal of a drug, a small spherical hemoglobin crystal, or a solution containing hemoglobin.

For applications in which the physical stability of the films is important, amino acid sequence motifs containing cysteine (or some other type of sulfhydryl-containing amino acid) may be selected from the library of motifs identified using the methods discussed above, or designed de novo using the principles described above. Polypeptides can then be designed and fabricated based on the selected or designed amino acid sequence motifs. Once the polypeptides have been synthesized chemically or produced in a host organism, ELBL assembly of cysteine-containing peptides is done in the presence of a reducing agent, to prevent premature disulfide bond formation. Following assembly, the reducing agent is removed and an oxidizing agent is added. In the presence of the oxidizing agent disulfide bonds form between cysteine residues, thereby “locking” together the polypeptide layers that contain them.

This “locking” method may be further illustrated using the following specific example of microcapsule fabrication. First, designed polypeptides containing cysteine are used to form multilayers by ELBL on a suitably charged spherical surface, normally in aqueous solution at neutral pH and in the presence of dithiothreitol (“DTT”), a reducing agent. Next, DTT is removed by filtration, diffusion, or some other similar method known in the art, causing cysteine to form from pairs of cysteine side chains and thereby stabilizing the film. If the peptide multilayers are constructed on a core particle containing the materials one wishes to encapsulate, for instance a crystalline material, the fabrication process is complete and the core particle can thereafter be made to dissolve in the encapsulated environment, for example by a change of pH. If, however, the multilayers are constructed on a “dummy” core particle, the core must be removed. In the case of melamine formaldehyde particles (“MF”), for example, the core is ordinarily dissolved by decreasing the pH—dissolution is acid-catalyzed. Following dissolution of the core, the pH of solution is adjusted to 4, where partial charge on the peptide polyanions makes the microcapsules semi-permeable (compare Lvov et al. (2001) Nano Letters 1:125, which is hereby incorporated herein in its entirety). Next, 10 mM DTT is added to the microcapsule solution to reduce cystine to cysteine. The microcapsules may then be “loaded” by transferring them to a concentrated solution of the material to be encapsulated, for example a protein (ibid.). The protein enters the microcapsules by moving down its concentration gradient. The encapsulated protein is “locked in” by removal of reductant and addition of oxidant, thereby promoting the reformation of disulfide bonds.

A schematic of the cysteine “locking” and “unlocking” method of the present invention is shown in FIG. 4. Cysteine can form both intra- and inter-molecular disulfide bonds. Further, disulfide bonds can be formed between molecules in the same layer or adjacent layers, depending on the location of cysteine-containing peptides in the film. Referring to FIG. 4( a), basic polypeptides 2 are linked by disulfide bonds 3 in all layers in which the basic peptides contain cysteine. The acidic peptides of the intervening layer (represented in the figure by a translucent layer 4) do not contain cysteine. However, alternating layers continue to attract each other electrostatically, if the acidic and basic side chains are charged at the pH of the surrounding environment. Referring to FIG. 4( b), disulfide bonds are shown between layers. Such structures will form when both the acidic and basic polypeptides (i.e., alternating polypeptide layers) used for ELBL contain cysteine and the procedure used has been suitable for disulfide bond formation. Referring to FIG. 4( c), reduction and oxidation reactions are used to regulate the release of encapsulated compounds 5 by breaking and forming disulfide bonds 3, respectively, and thereby regulating the diffusion of particles through the capsule wall.

The cysteine “locking” and “unlocking” is a novel way of regulating the structural integrity and permeability of ELBL films. It is known in the art that glutaraldehyde can be used to cross-link proteins, and this chemical could therefore be used to stabilize polypeptide films. Glutaraldehyde cross-linking, however, is irreversible. In contrast, the cysteine “locking” and “unlocking” method of the present invention is reversible and, therefore, offers better control over structure formation and, importantly, use of the films and capsules that can be fabricated using the present invention. Blood is an oxidizing environment. Thus, in certain biomedical applications, for example artificial red blood cells or drug delivery systems fabricated from designed polypeptides, exposing Cys-crosslinked polypeptide film to the blood or some other oxidizing environment after the formation of disulfide bonds is not expected to cause those bonds to be broken. Finally, it should also be noted that applications involving non-natural amino acids would replace Cys with some other sulfhydryl-containing amino acid type. For example, a sulfhydryl could be added to P-amino acids such as D,L-β-amino-β-cylohexyl propionic acid; D,L-3-aminobutanoic acid; or 5-(methylthio)-3-aminopentanoic acid (see http://www.synthatex.com).

Biocompatibility

Biocompatibility is a major design concern in biomedical applications. In such applications, the practitioner of the present invention will aim to identify genomic or proteomic information that will yield “immune inert” polypeptides, particularly if the fabricated or coated object will make contact with circulating blood. For purposes of the present invention, it is preferred that the selection process discussed in Part (A)(1) above be used to analyze the amino acid sequences of blood proteins. This will maximize the odds of minimizing the immune response of an organism.

Computer algorithms exist for predicting the antigenicity of an amino acid sequence. Such methods, however, are known in the art to be semi-reliable at best. In the present invention, the sequence motifs identified using the selection method discussed above in Part (A)(1) are highly polar. The motifs must, therefore, occur on the surface of the native state of the proteins of which they are part of the sequence. The “surface” is that part of a folded protein that is in contact with the solvent or inaccessible to the solvent solely because of the granular nature of water. The “interior” is that part of a folded protein that is inaccessible to solvent for any other reason. A folded globular soluble protein is like an organic crystal, the interior being as densely packed as in a crystal lattice and the exterior being in contact with the solvent, water. Because of their charge properties, the polypeptide sequence motifs identified using the method of the present invention must occur mostly, if not exclusively, on the surface of a protein. Thus, all of the sequence motifs identified in human blood proteins using the selection process of the current invention are effectively always in contact with the immune system while the protein is in the blood. This holds for all conformations of the protein that might become populated in the bloodstream, including denatured states, because it is highly energetically unfavorable to transfer a charge from an aqueous medium to one of low dielectric (as occurs in a protein interior). Accepted biochemical principles indicate, therefore, that the polypeptides designed from blood proteins using the method of the present invention will either not illicit an immune response or will elicit a minimal immune response. For the same reasons, polypeptides designed using the method of the present invention should be biocompatible. All sequence motifs identified from genomic data using the selection process of the current invention, not only those in blood proteins, should be biocompatible, though the extent of immune response or any other type of biological response may well depend on specific details of a sequence motif. (Because the polypeptide sequences on which the motifs are based actually occur in the organism for which the film as been fabricated, this approach will, at least in principle, work equally well for any type of organism. For instance, the approach may be of significant value to veterinary science.) Both immune response and biocompatibility are important regarding the use of the designed peptides in biomedical applications, including, without limitation, the manufacture of artificial red blood cells, drug delivery systems, or polypeptides for fabrication of biocompatible films to coat implants for short-term or long-term introduction into an organism.

Bioactivity

In some applications of polypeptide thin films, coatings, or microcapsules, it is desirable to modify the design of the polypeptides to include a functional domain for use in some layer of the structure, often the outermost. A functional domain in this context is an independently thermostable region of a protein that has specific biofunctionality (e.g., binding phosphotyrosine). It is well known in the art that such biofunctionality may be integrated with other functionalities in a multi-domain protein, as for example in the protein tensin, which encompasses a phosphotyrosine binding domain and a protein tyrosine phosphatase domain. The inclusion of such a domain in a designed polypeptide could function in a number of ways, including without limitation specific ligand binding, targeting in vivo, bio sensing, or biocatalysis.

In one embodiment, a multilayer film comprises a first layer composite polypeptide comprising one or more surface adsorption regions covalently linked to one or more functional regions, wherein the first layer composite polypeptide and the one or more surface adsorption regions have the same polarity. The surface adsorption regions comprise one or more amino acid sequence motifs. The first layer composite polypeptide is at least 15 amino acids long, and has a solubility in aqueous solution at pH 4 to 10 of greater than 50 μg/mL. In one embodiment, the one or more surface adsorption regions and the one or more functional regions have the same polarity. In another embodiment, the solubility of the first layer composite polypeptide at pH 4 to 10 is greater than or equal to about 1 mg/mL. The solubility is a practical limitation to facilitate deposition of the polypeptides from aqueous solution. A practical upper limit on the degree of polymerization of a composite polypeptide is about 1,000 residues. It is conceivable, however, that longer composite polypeptides could be realized by an appropriate method of synthesis.

In one embodiment, a composite polypeptide comprises one functional region and one surface adsorption region, wherein the surface adsorption region comprises two amino acid sequence motifs. In another embodiment, a composite polypeptide (4) comprises one functional region (3) and two surface adsorption regions (1,2), one attached to the N-terminus of the functional region and one attached to the C-terminus of the functional region, wherein each surface adsorption region comprises one or more amino sequence motifs and the two surface adsorption regions are the same or different and have the same polarity. (FIG. 13) The purpose of the surface adsorption region(s) is to enable adsorption of the polypeptide onto an oppositely charged surface in order to build a multilayer film. The purpose of the functional region(s) is to provide specific functionality to the film, such as, for example, a biological function. Other types of function are possible. For example, in one embodiment, the functional region confers on the polypeptide multilayer film the ability to bind calcium divalent cations with a high degree of specificity, as in the case where the functional region is a known calcium binding motif from a protein, e.g., the calcium binding loop of human milk protein α-lactalbumin. There is nothing fundamentally biological about the ability of a multilayer film to bind calcium ions with high specificity, even if some biological macromolecules do exhibit such ability and the peptidic structure which enables such binding has been engineered into a multilayer film.

The number of surface adsorption regions in a composite polypeptide relative to the number and/or length of the functional regions is related to the solubility requirement. For example, if the functional region is a short amino acid sequence such as “RGD”, that is, arginine-glycine-aspartic acid, only one amino acid sequence motif of at least 12 amino acid residues will be required to adsorb the composite polypeptide onto a suitably charged surface. If, by contrast, the functional region is a soluble folded structural domain of a protein comprising, for example, 120 amino acid residues, two amino acid sequence motifs will typically be sufficient to impart enough charge for the composite polypeptide to be water soluble and suitable for adsorption. The motifs could be contiguous and located at the N-terminus of the domain, contiguous and located at the C-terminus of the domain, or noncontiguous with one at the N-terminus and one at the C-terminus.

The combined length of the surface adsorption regions is related more to the dissipation due to thermal energy, which must be overcome for composite peptide adsorption to occur spontaneously, than to the number amino acid residues in the functional region of the composite peptide. Therefore, increasing the degree of polymerization of the functional region by a factor of two does not necessarily require surface adsorption regions twice as long for effective binding of the surface adsorption regions of the composite peptide. The physical basis of adsorption of a composite peptide to a surface is electrostatic attraction (and release of counterions to bulk solution), the precise mass of the domain is of secondary importance on the length scale of nanometers, and the main “force” counteracting composite peptide adsorption is thermal energy. In view of this, one of skill in the art can readily design surface adsorption regions that are suitable for physical adsorption to a surface of the particular functional region of interest.

A functional region comprises 3 to about 250 amino acid residues. The term functional region includes both functional motifs and functional domains. Functional motifs comprise relatively few amino acid residues and therefore generally do not have a compact or persistent three-dimensional structure; nevertheless, they can exhibit specific functionality, as with some peptide hormones and neuropeptides, and they can comprise elements of secondary structure such as α-helices and β-sheets. An example of a functional motif is provided by the RGD sequence of the extracellular matrix protein fibronectin. When the functional unit is a functional motif, it will typically comprise 3 to about 50 amino acid residues. When the functional region is a domain, it will typically comprise about 50 to about 250 amino acid residues.

A functional domain is defined herein as at least a portion of a polypeptide which, when folded, creates its own hydrophobic core. A native protein, for example, may contain a plurality of structural domains, each of which acts as an independent unit of structure and function. The biological function of one domain can be completely independent of the function of another, as in the case of a catalytic domain and a binding domain in the same polypeptide chain, where the two domains do not interact with each other at all. Structural interactions between domains in a native protein are not only possible, but relatively common; in such cases the interaction between one structural domain and another structural domain can be viewed as a type of quaternary structure.

As used herein, a functional domain typically has a minimum of about 50 amino acid residues and a maximum of about 250 amino acid residues. In principle, any functional domain from a protein can be employed in a composite peptide as outlined herein so long as the composite polypeptide has the appropriate aqueous solubility for ELBL deposition. In one embodiment, the functional domain has a water solubility at pH 4 to 10 of greater than 50 μg/mL. In another embodiment, the functional domain has a water solubility at pH 4 to 10 of greater than or equal to 1 mg/mL. In yet another embodiment, the first layer composite polypeptide comprises at least two amino acid sequence motifs when the functional unit comprises a functional domain.

The composite polypeptide, when it comprises a functional motif instead of a functional domain, will typically have a net charge per residue of greater than or equal to 0.4. If, however, the functional motif has a net charge per residue of less than 0.4, the one or more surface adsorption regions will typically have a net charge per residue of greater than 0.4 to compensate and give the composite polypeptide the appropriate charge properties for solubility and physical adsorption.

Suitable functional regions for inclusion in composite polypeptides include cysteine-containing motifs or a protease recognition sites to control film stability and/or the release of encapsulated materials from films/capsules; T-cell epitopes, B-cell epitopes, or a cytotoxic T lymphocyte epitopes for control of immunogenicity; sequences suitable for attachment of a saccharide or polysaccharide by enzymatic catalysis, for example, as in N-linked or O-linked glycosylation; peptide recognition sequences in extracellular matrix proteins for control of surface functionality and tissue engineering; sequences from antibacterial peptides for control of anti-microbial properties; extracellular domains of transmembrane receptors for specific targeting in vivo; and cation binding motifs such as EF hand motifs for control of divalent cation binding.

In one non-limiting embodiment, the functional region of a composite peptide comprises a protease recognition sequence. Suitable protease recognition sequences include, for example, the factor Xa recognition sequence Ile-Glu/Asp-Gly-Arg↓, the enterokinase recognition sequence Asp-Asp-Asp-Asp-Lys↓, the thrombin recognition sequence Leu-Val-Pro-Arg↓Gly-Ser, the TEV protease recognition sequence Glu-Asn-Leu-Tyr-Phe-Gln↓Gly, the PreScission™ protease recognition sequence Leu-Glu-Val-Leu-Phe-Gln↓Gly-Pro, and the like.

In another non-limiting embodiment, the functional region of composite peptide comprises a T-cell epitope, a B-cell epitope, or a cytotoxic T-cell epitope. As used herein, “T-cell epitope” refers to any peptidic antigenic determinant which is recognized by T-cells. As used herein, “B-cell epitope” refers to any peptidic antigenic determinant which is recognized by B-cell immunoglobulin receptors and is capable of eliciting the production of antibodies with appropriate help from T cells when administered to an animal. As used herein, “cytotoxic T lymphocyte epitope” refers to an any peptidic antigenic determinant which is recognized by cytotoxic T-lymphocytes. The epitopes are polypeptides produced by viruses, bacteria, fungi, or parasites. In some cases the epitopes may be polypeptides to which saccharides or oligosaccharides are attached or could be attached, e.g., by N-linked or O-linked glycosylation.

Glycosylation is a common and highly diverse protein modification reaction which occurs in most eukaryotic cells. Such modifications can be divided into two general categories, N-linked and O-linked. In the former, the carbohydrate moiety is attached to the amide nitrogen of the side chain of asparagine, when asparagine is part of the consensus sequence Asn-X-Ser/Thr. This signal is necessary but not sufficient for glycosylation, e.g., X cannot be Pro, and if Pro occurs shortly downstream of Ser/Thr glycosylation is inhibited. In O-linked glycosylation, the carbohydrate moiety is attached to the hydroxyl oxygen of Ser or Thr; it also occurs as a primary modification of tyrosine and a secondary modification of 5-hydroxylysine and 4-hydroxyproline. There is a high frequency of occurrence of Pro, Ser, Thr, and Ala residues around O-linked glycosylation sites.

Linear epitopes are segments composed of a continuous string of amino acid residues along the polymer chain. Typical linear epitopes have a length of about 5 to about 30 amino acids. Conformational epitopes, by contrast, are constituted by two or more sequentially discontinuous segments that are brought together by the folding of the antigen into its native structure. Conformational epitopes generally correspond to longer peptide chains than do linear epitopes. Either type of epitope could serve as the functional region of a composite polypeptide for LBL.

In another non-limiting embodiment, the functional region of a composite peptide comprises a sequence from an antibacterial peptide. Antimicrobial peptides include, for example, inhibitory peptides that slow the growth of a microbe, microbiocidal peptides that are effective to kill a microbe (e.g., bacteriocidal and virocidal peptide drugs, sterilants, and disinfectants), and peptides effective for interfering with microbial reproduction, host toxicity, or the like. Examples of antimicrobial peptides include nisin, carnobacteriocins B2 and BM1, leucocin A, mesentericin Y105, sakacins P and A, and curvacin A.

In another non-limiting embodiment, the functional region of a composite peptide is a peptide recognition sequence for extracellular matrix (ECM) recognition. One such sequence, RGD, occurs in various extracellular matrix proteins and is a key recognition sequence for integrin transmembrane receptor molecules. Another ECM recognition sequence is GFOGER, GLOGER, or GASGER, wherein ‘O’ represents hydroxyproline. These are recognition sequences in collagen for collagen-binding integrins. Both types of recognition sequence are suitable for the functional region of a composite peptide for LBL.

In another non-limiting embodiment, the functional region of a composite peptide is a signaling motif for recognition by a cell surface receptor for specific targeting in vivo. The extracellular region of the receptor will bind the peptide or protein signal ligand with notable specificity. The peptide or protein ligand could be a peptide hormone (e.g., insulin, vasopressin, oxytocin) a growth factor (e.g, VEGF, PDGF, FGF), or the like. Such signal sequences are suitable for the functional region of a composite peptide for LBL. In such cases, the functional region of a composite peptide for LBL will often be a functional motif. Similarly, the extracellular region of a membrane receptor is suitable for the functional region of a composite peptide for LBL. In such cases, the functional region of a composite peptide for LBL will often be a functional domain.

In another non-limiting embodiment, the functional region of a composite peptide for LBL is a cation binding motif such as an EF hand motif for control of divalent cation binding. Other cation binding domains include the C2 domain, the “VSFASSQQ” motif, and the dockerin domain.

In another non-limiting embodiment, the functional region of a composite peptide is a phosphotyrosine recognition domain, such as a protein tyrosine phosphatase domain, a C2 domain, an SH2 domain, or a phosphotyrosine binding domain. Such domains from numerous different proteins are known to be independent folding units.

In another non-limiting embodiment, the functional domain is a polyproline recognition domain, such as an SH3 domain.

Each of the independent regions (viz., functional regions and surface adsorption regions) of the composite polypeptide can be synthesized separately by solution-phase synthesis, solid-phase synthesis, or genetic engineering of a suitable host organism. Solution-phase synthesis is the method used for production of most of the approved peptide pharmaceuticals on the market today. An N-terminal surface adsorption region (1), a C-terminal surface adsorption region (2) and a functional region (3) can be synthesized separately. (FIG. 14) The solution-phase method can be used to synthesize relatively long peptides and even small proteins. The longest peptides that have made by the solution-phase method are calcitonins (32mers). More commonly, the method is used to produce small- or medium-length peptides in quantities of up to hundreds of kilograms. It is possible to produce such large quantities of the desired peptides in a facility that follows good manufacturing practices.

Alternatively, the various independent regions can be synthesized together as a single polypeptide chain by solution-phase synthesis, solid-phase synthesis, or genetic engineering of a suitable host organism. The choice of approach in any particular case will be a matter of convenience or economics.

If the various functional regions and surface adsorption regions are synthesized separately, once purified, for example, by ion exchange chromatography followed by high-performance liquid chromatography, they are joined by peptide bond synthesis. For example, an N-terminal surface adsorption region (1), a functional motif (3), and a C-terminal surface adsorption region (3) can be synthesized separately and joined to form a composite polypeptide (3) (FIG. 15). The approach is similar to so-called hybrid synthesis, wherein peptide segments with fully protected side chains are synthesized by the solid-phase technique and then joined by peptide bonds in a solution-phase or solid-phase procedure. This hybrid approach has been applied to the synthesis of T20, a 36-amino acid residue peptide, but it has not been widely exploited.

FIG. 17 illustrates an embodiment of a “composite” polypeptide comprising 2 surface adsorption regions (120 and 130) and 1 functional region (110). 120 is the N-terminal surface absorption region. 130 is the C-terminal absorptive region. Each surface adsorption region comprises one or more motifs. A “composite” polypeptide is a unique combination of surface adsorption region(s) and functional region(s) in a single polypeptide chain. Linker peptide sequences (140) can be used to generate a composite polypeptide comprising multiple functional regions in a single polypeptide chain. In one embodiment, functional region 110 can be a small functional region comprising from about 50 to about 130 amino acid residues, and having a diameter of about 2 nm. In an alternate embodiment, functional region 110 can be a large functional region comprising about 250 amino acid residues, and having a diameter of about 4 nm. The length of 16 amino acid residues in extended conformation is approximately 5.5 nm.

FIG. 18 (200 and 300) illustrate embodiments of a “composite” polypeptide comprising 2 surface adsorption regions (120 and 130) and 1 functional region (111, 112), attached to a surface (150). Embodiment 200 of FIG. 18 illustrates a “composite” polypeptide comprising 2 surface adsorption regions (120 and 130) and 1 functional region (111), attached to a surface (150), wherein functional region 111 represents a small functional region comprising from about 50 to about 130 amino acid residues, and having a diameter of about 2 nm. Small functional region 111 can be a short peptide sequence, e.g., RGD. 120 is the N-terminal surface absorption region. 130 is the C-terminal absorptive region.

FIG. 18 (300) further illustrates an alternate embodiment of a “composite” polypeptide comprising 2 surface adsorption regions (120 and 130) and 1 functional region (110), wherein functional region 112 represents a large functional region comprising about 250 amino acid residues and having a diameter of about 4 nm. Large functional domain 112 can be the domain of a protein, e.g., the PTP domain of tensin. 120 is the N-terminal surface absorption region. 130 is the C-terminal absorptive region.

An advantage of a modular approach to building composite peptides includes taking advantage of the previously described amino acid sequence motif technology, minimizing risk. Other advantages include generality of the approach for nearly any conceivable functional region; and chemically distinct peptides containing identical or different functional regions and identical or different surface adsorption regions of the same sign of electronic charge can be adsorbed simultaneously, creating a unifunctional or a multifunctional surface as desired. Advantages of synthesizing the surface adsorption regions and the functional regions as individual building blocks include: the ability to pre-make and store practically indefinitely (by lyophilization) the individual building blocks for ready availability; the low cost of production of composite peptides of specific functionality by use of warehoused building blocks prepared in large quantities; rapid preparation of the composite peptide in comparison to straight solid-phase, solution-phase or biotic synthesis; rapid response to new developments concerning functional regions due to the modular synthetic approach; and the use of completely synthetic peptides and polypeptide multilayer-based materials as a means of minimizing contamination by microbes and simplifying approval of products by the US Food and Drug Administration.

Uses for Polypeptides Designed Using the Method of the Present Invention

As noted above, polypeptides of suitable design are excellent materials for ELBL, and polypeptide film structures formed using ELBL will be useful in a large number of different types of applications. Polypeptides designed using the method of the present invention have been shown to be useful for ELBL of film structures for possible applications in biomedical technology, food technology, and environmental technology. For example, such polypeptides could be used to fabricate artificial red blood cells.

Artificial Red Blood Cells

A number of different approaches have been taken to red blood cell substitute development. One approach involves the use of perfluorocarbons. Perfluorocarbon emulsions contain synthetic fluorinated hydrocarbons capable of binding oxygen and delivering it to tissues. This approach however, increases reticulo-endothelial cell blockage. The perfluorocarbons can become trapped in the reticulo-endothelial system, which may result in adverse consequences.

Another approach focuses on antigen camouflaging, which involves coating red blood cells with a biocompatible polymer called polyethylene glycol (PEG). The PEG molecules form permanent covalent bonds on the surface of the cell. The coating effectively hides the antigenic molecules on the surface of the red blood cells, so that the blood recipient's antibodies do not recognize the cells as foreign. For example, the immune system of a normal person who has type A blood will naturally have antibodies that recognize antigens on the surface of type B red blood cells, leading to cell destruction. The attachment of PEG to the surface of a type B red blood cell “camouflages” the surface of the cell, so that its surface antigens can no longer be recognized by the immune system and the antigenically-foreign red blood cells will not be destroyed as quickly (see Pargaonkar, N. A., G. Sharma, and K. K. Vistakula. (2001) “Artificial Blood: Current Research Report,” which is hereby incorporated by reference in its entirety).

A number of diseases, including thalassemia, that require repeated blood transfusions are often complicated by the development of antibodies to “minor” red cell antigens. This “allosensitization” can render these patients almost impossible to transfuse, rendering the situation life-threatening. In in vitro testing, the PEG-modified red cells appear not to trigger allosensitization and may also be useful in clinical situations where allosensitization has already occurred (see Scott, M. D. et al. (1997) “Chemical camouflage of antigenic determinants: Stealth erythrocytes,” Proc. Natl. Acad. Sci. USA. 94 (14): 7566-7571, which is hereby incorporated by reference in its entirety).

Other approaches involve purified hemoglobin. Unmodified cell-free hemoglobin has known limitations. These include oxygen affinity that is too high for effective tissue oxygenation, a half-life within the intravascular space that is too short to be clinically useful, and a tendency to undergo dissociation into dimers with resultant renal tubular damage and toxicity. Because of these limitations, hemoglobin used to make a cell-free red blood cell substitute must be modified. A number of modification techniques have been developed. Hemoglobin can be cross-linked (a covalent bond between two molecules is made by chemical modification) and polymerized using reagents such as glutaraldehyde. Such modifications result in a product that has a higher P₅₀ (partial pressure of oxygen at which 50% of all oxygen-binding sites are occupied) than that of normal hemoglobin, and an increase in the plasma half-life of up to 30 hours. The source of the hemoglobin for this purpose can be human (outdated donated blood), bovine, or human recombinant. The solution of modified hemoglobin is prepared from highly purified hemoglobin and taken through various biochemical processes, to eliminate phospholipids, endotoxins, and viral contaminants (see Nester, T. and Simpson, M (2000) “Transfusion medicine update,” Blood Substitutes, which is hereby incorporated by reference in its entirety). Biopure Corporation (Cambridge, Mass.) has been using modified hemoglobin for their product, Hemopure.

The main potential adverse effect of modified hemoglobin solutions is an increase in systemic and pulmonary vascular resistance that may lead to a decrease in cardiac index. Decreases in the cardiac index may impair optimum oxygen delivery and outweigh the advantage of an oxygen-carrying solution (see Kasper S. M. et al. (1998) “The effects of increased doses of bovine hemoglobin on hemodynamics and oxygen transport in patients undergoing preoperative hemodilution for elective abdominal aortic surgery,” Anesth. Analg. 87: 284-91, which is hereby incorporated by reference in its entirety). One study has examined the utility of these solutions in the acute resuscitation phase of unstable trauma patients. Design of the study, however, was poor, and any role of the solutions in influencing ultimate patient outcome was unclear (see Koenigsberg D. et al. (1999) “The efficacy trial of diaspirin cross-linked hemoglobin in the treatment of severe traumatic hemorrhagic shock,” Acad. Emerg. Med. 6: 379-80, which is hereby incorporated by reference in its entirety).

Many of the problems of cell-free hemoglobin can be overcome by encapsulating it with an artificial membrane. Liposomes are being used to encapsulate hemoglobin for use as a blood substitute. The approach is technically challenging because not only must the hemoglobin be prepared, it must be encapsulated in relatively high concentration and yield. The final products must be sterile and the liposomes must be relatively uniform in size.

Encapsulated hemoglobin has several advantages over cell-free hemoglobin. Firstly, the artificial cell membrane protects hemoglobin from degradative and oxidative forces in the plasma. Secondly, the membrane protects the vascular endothelium from toxic effects of hemoglobin. These relate to heme loss, the production O₂ free radicals and vasoconstrictor effects of NO binding. Thirdly, encapsulation greatly increases the circulating persistence of the hemoglobin. Moreover, encapsulated hemoglobin can be freeze-dried for convenient storage.

Liposomal encapsulation involves phospholipids, as in cell membranes. One major problem associated with liposomal encapsulation, however, is that it is very difficult to regulate the average size and distribution of liposomes. Another is that unlike red blood cells, liposomes are often not very stable, as they ordinarily lack an organized cytoskeleton. Yet another problem is that liposomes often consist of multiple layers of phospholipid. (A recent review of blood substitute development is presented in Stowell et al. (2001) Progress in the development of RBC substitutes, Transfusion 41:287-299, which is hereby incorporated by reference in its entirety. See also Chang, T. 1998 “Modified hemoglobin-based blood substitutes: cross linked, recombinant and encapsulated hemoglobin,” Artificial Cell 74 Suppl 2:233-41, which is hereby incorporated by reference in its entirety.)

Red blood cell substitutes employing polypeptides designed using the method of the present invention should offer several advantages over approaches to the development of red blood cell substitutes known in the art, including, without limitation, superior oxygen and carbon dioxide binding functionality, lower production cost (large-scale and therefore low-cost production is possible because bacteria can be used to mass-produce the peptides and because peptide ELBL can be automated), the possibility of using suitable preparations of hemoglobin as a template for ELBL, polypeptide biodegradability, the immune “inertness” of designed polypeptides based on blood protein structure, and the structural stability exhibited by designed polypeptide films, which exceeds that of liposomes. Polypeptide ELBL assembly yields semi-porous films, minimizing the amount of material required for fabricating a means of encapsulation and enabling glucose, oxygen, carbon dioxide, and various metabolites to diffuse as freely through the films as a lipid bilayer. In contrast, other polymers potentially suitable for this purpose have undesirable side effects—for example, polylactide degrades into lactic acid, the substance that causes muscle cramps, and poly (styrene sulfonate) is not biocompatible.

Microcapsules could be formed of designed polypeptides to encapsulate hemoglobin to serve as a red blood cell substitute. Hemoglobin polypeptide microcapsules could also be engineered to incorporate enzymes, including superoxide dismutase, catalase, and methemoglobin reductase, which are ordinarily important for red blood cell function. Moreover, the nanofabricated microcapsules can predictably be dehydrated, suggesting that artificial red blood cells made as described herein could be dehydrated, without loss of function, particularly because hemoglobin can be lyophilized (i.e., freeze-dried) and reconstituted without loss of function, and polyion films are stable to dehydration. This will be important for long-term storage, transport of blood substitutes, battlefield applications (particularly in remote locations), and space exploration.

Polypeptides designed using the method of the present invention could also be used for drug delivery.

Drug Delivery

Micron-sized “cores” of a suitable therapeutic material in “crystalline” form can be encapsulated by designed polypeptides, and the resulting microcapsules could be used for drug delivery. The core must be insoluble under some conditions, for instance high pH or low temperature, and soluble under the conditions where controlled release will occur. The surface charge on the crystals can be determined by ζ-potential measurements (used to determine the charge in electrostatic units on colloidal particles in a liquid medium). The rate at which microcapsule contents are released from the interior of the microcapsule to the surrounding environment will depend on a number of factors, including the thickness of the encapsulating shell, the polypeptides used in the shell, the presence of disulfide bonds, the extent of cross-linking of peptides, temperature, ionic strength, and the method used to assemble the peptides. Generally, the thicker the capsule, the longer the release time—the principle resembles that of gel filtration chromatography.

Some work has been done on sustained release from ELBL microcapsules (see Antipov, A., Sukhorukov, G. B., Donath, E., and Möhwald, H. (2001) J. Phys. Chem. B, 105:2281-2284 and Freemantle, M. (2002) Polyelectrolyte multilayers, Chem. Eng. News, 80: 44-48, both of which are incorporated herein by reference in their entireties). Polyelectrolytes that have been used are PSS, PAH, PAA, PVS, PEI, and PDDA.

Polypeptides designed using the method of the present invention should offer a number of advantages in the context of drug delivery, including without limitation control over the physical, chemical, and biological characteristics of the microcapsule; the ability to make capsules with a diameter of less than 1 mm, making the capsules suitable for injection; low likelihood of eliciting an immune response; generally high biocompatibility of capsules; control over the diffusive properties of the microcapsules by varying the thickness of the layers and using cysteine, as discussed below; the ability to target specific locations by modification of the microcapsule surface using the highly reactive sulfhydryl groups in cysteine (as is well known in the art, free sulfhydryl groups, free amino groups, and free carboxyl groups are sites to which molecules for specific targeting could be attached), or by incorporation of a specific functional domain in the design of the polypeptide; and the ability of microstructures to be taken up by cells using either endocytosis or pinocytosis.

Polypeptides designed using the method of the present invention could also be used for antimicrobial coatings.

Antimicrobial Coatings

The method of the present invention could be used to manufacture films encompassing antimicrobial peptides. For example, one suitable sequence might be Histatin 5, which occurs in humans:

(SEQ ID NO: 8) Asp Ser His Ala Lys Arg His His Gly Tyr Lys Arg Lys His Glu Lys His His Ser His Arg Gly Tyr

The preponderance of positive charge at slightly basic pH makes this sequence quite suitable for ELBL. It could be appended to a peptide designed using the method of the present invention, resulting in an antimicrobial peptide suitable for use in ELBL. This peptide could be used as an anti-biofouling coating. For instance, the peptide could be used to form a coating on devices used for implantation.

There are also a number of other areas in which polypeptides designed using the method of the present invention could be useful.

Other Uses

Other possible uses for peptides designed using the method of the present invention include without limitation food covers, wraps, and separation layers; food casings, pouches, bags, and labels; food coatings; food ingredient microcapsules; drug coatings, capsules, and microcapsules; disposable food service items (plates, cups, cutlery); trash bags; water-soluble bags for fertilizer and pesticides; microcapsules for fertilizer and pesticides; agricultural mulches; paper coatings; loose-fill packaging; disposable medical products (e.g. gloves and gowns); and disposable diapers.

Fabrication

Once amino acid sequence motifs have been selected from those identified using the method discussed in Part (A)(1) above or designed de novo, the designed polypeptide is synthesized using methods well known in the art, such as solid phase synthesis and F-moc chemistry or heterologous expression following gene cloning and transformation. Designed polypeptides may be synthesized by a peptide synthesis company, for example SynPep Corp. (Dublin, Calif.), produced in the laboratory using a peptide synthesizer, or produced by recombinant methods.

In one embodiment, a designed polypeptide, e.g., a first layer polypeptide, comprises a plurality of individual amino acid sequence motifs joined in tandem to form a single polypeptide chain. The same motif may be repeated, or different motifs may be joined in designing a polypeptide for ELBL. Moreover, functional domains may be included, as discussed above. Amino acids such as glycine or proline could be used to link the sequence motifs, so long as the overall charge properties of the polypeptide are maintained, that is, the magnitude of the net charge on the polypeptide per residue is 0.4. In one embodiment, a linker comprises 1-4 amino acid residues, for example, 1-4 glycine or proline resides. In addition, amino acids other than the 20 usual ones could be included in the motifs themselves, depending on the properties desired of the polypeptide. Other properties could likewise be specified by design requirements, using methods known in the art. For example, proline could be included for turn formation, glycine for chain flexibility, and histidine for pH-sensitive charge properties near neutral pH. “Hydrophobic” amino acids could also be included—hydrophobic residue content could play a role in assembly behavior and contribute to layer stability in a way resembling the hydrophobic stabilization of globular proteins.

In one embodiment, a first layer polypeptide comprises one or more amino acid sequence motifs, wherein the polypeptide is at least 15 amino acids in length and the ratio of the number of charged residues of the same sign minus the number of residues of the opposite sign to the total number of residues in the polypeptide is greater than or equal to 0.4 at pH 7.0. In other words, the magnitude of the net charge on the polypeptide per residue is greater than or equal to 0.4. In another embodiment, the ratio of the number of charged residues of the same sign minus the number of residues of the opposite sign to the total number of residues in the polypeptide is greater than or equal to 0.5 at pH 7.0. In other words, the magnitude of the net charge on the polypeptide per residue is greater than or equal to 0.5.

In one embodiment, a designed polypeptide is greater than or equal to 15 amino acid residues long. In other embodiments, a designed polypeptide is greater than 18, 20, 25, 30, 32 or 35 amino acids long. The reason for this is that the entropy loss per molecule is so thermodynamically unfavorable for short polymers that adsorption to an oppositely-charged surface is inhibited, even if the polypeptide has a charge per unit length of 1; long polyelectrolytes adsorb better than short ones. This is illustrated in FIG. 12. The average molecule masses of the peptides utilized for the length-dependence studies were 1,500-3,000 Da (poly-L-glutamate, “small”), 3,800 Da (poly-L-lysine, “small”), 17,000 Da (poly-L-glutamate, “medium”), 48,100 Da (poly-L-lysine, “medium”), 50,300 Da (poly-L-glutamate, “large”), and 222,400 Da (poly-L-lysine, “large”). The data shown in FIG. 12 clearly indicate that ELBL depends on length of peptide. Inclusion of Cys enables the use of relatively small peptides for ELBL, because the sulfhydryl group can be used to form disulfide crosslinks between polypeptides.

Film Assembly

A method of making a designed polypeptide multilayer film comprises depositing a plurality of layers of oppositely charged chemical species on a template, wherein at least one layer comprises a designed polypeptide. Successively deposited polyelectrolytes will have opposite net charges. In one embodiment, deposition of a designed polypeptide (or other polyelectrolyte) comprises exposing the substrate to an aqueous solution comprising a designed polypeptide (or other polyelectrolyte) at a pH at which it has a suitable net charge for ELBL. In other embodiments, the deposition of designed polypeptide or other polyelectrolyte on the substrate is achieved by sequential spraying of solutions of oppositely charged polypeptides. In yet other embodiments, deposition on the substrate is by simultaneous spraying of solutions of oppositely charged polylectrolytes.

In the ELBL method of forming a multilayer film, the opposing charges of the adjacent layers and the gain in entropy on release of counterions to solution together provide the driving force for assembly. It is not critical that polyelectrolytes in opposing layers have the same net linear charge density, only that opposing layers have opposite charges. The standard film assembly procedure includes forming aqueous solutions of the polyions at a pH at which they are ionized (i.e., pH 4-10), providing a substrate bearing a surface charge, and alternating immersion of the substrate into the charged polyelectrolyte solutions. The substrate is optionally washed in between deposition of alternating layer.

The concentration of polyion suitable for deposition of the polyion can readily be determined by one of ordinary skill in the art. An exemplary concentration is 0.1 to 10 mg/mL. Typically, the thickness of the layer produced is substantially independent of the solution concentration of the polyion during deposition in the stated range. For typical non-polypeptide polyelectrolytes such as poly(acrylic acid) and poly(allylamine hydrochloride), typical layer thicknesses are about 3 to about 5 Å, depending on the ionic strength of solution. Short polyelectrolytes typically form thinner layers than long polyelectrolytes. Regarding film thickness, polyelectrolyte film thickness depends on humidity as well as the number of layers and composition of the film. For example, PLL/PLGA films 50 nm thick shrink to 1.6 nm upon drying with nitrogen. In general, films of 1-2 nm to 100 nm or more in thickness can be formed depending on the hydration state of the film and the molecular weight of the polyelectrolytes employed in the assembly.

In addition, the number of layers required to form a stable polyelectrolyte multilayer film will depend on the polyelectrolytes in the film. For films comprising only low molecular weight polypeptide layers, a film will typically have 4 or more bilayers of oppositely charged polypeptides. For films comprising high molecular weight polyelectrolytes such as poly(acrylic acid) and poly(allylamine hydrochloride), films comprising a single bilayer of oppositely charged polyelectrolyte can be stable.

Experiments Example 1 Design of Polypeptides Based on Human Blood Protein Sequences and their Use in Polypeptide Film Fabrication

For this work, amino acid sequences were selected using the process described in Part (A)(1) above to identify sequence motifs in the primary structure of human blood proteins: Complement C3 (gi|68766) was the source of the anionic sequence motifs, and lactotransferrin (gi|4505043) the source of the cationic sequence motifs. As discussed above, blood protein sequences were used to minimize the immune response of patients into whom devices involving the polypeptides might be introduced (including, e.g. artificial red blood cells). In principle, this approach should be applicable for any organism having an immune system; it is not limited to humans. Polypeptides were synthesized by SynPep Corp. (Dublin, Calif.). The polypeptide sequences were:

(SEQ ID NO: 2) Tyr Glu Glu Asp Glu Cys Gln Asp Gly Glu Glu Asp Glu Cys Gln Asp Gly Glu Glu Asp Glu Cys Gln Asp Gly Glu Glu Asp Glu Cys Gln Asp (SEQ ID NO: 1) Tyr Arg Arg Arg Arg Ser Val Gln Gly Arg Arg Arg Arg Ser Val Gln Gly Arg Arg Arg Arg Ser Val Gln Gly Arg Arg Arg Arg Ser Val Gln (SEQ ID NO: 4) Tyr Glu Glu Asp Glu Cys Gln Asp Gly Glu Glu Asp Glu Cys Gln Asp Gly Glu Glu Asp Glu Cys Gln Asp Gly Glu Glu Asp Glu Cys Gln Asp Gly Glu Glu Asp Glu Cys Gln Asp Gly Glu Glu Asp Glu Cys Gln Asp (SEQ ID NO: 3) Tyr Arg Arg Arg Arg Ser Val Gln Gly Arg Arg Arg Arg Ser Val Gln Gly Arg Arg Arg Arg Ser Val Gln Gly Arg Arg Arg Arg Ser Val Gln Gly Arg Arg Arg Arg Ser Val Gln Gly Arg Arg Arg Arg Ser Val Gln

The amino acid residues are represented by the three-letter code given above. One glycine was introduced between each 7-residue motif to inhibit secondary structure formation. Glycine was selected for this purpose because it allows the greatest variability in combination of dihedral angles (see Ramachandran, G. N. and Saisekharan, V. (1968), Adv. Prot.ein Chemistry, 23:283, which is incorporated by reference herein in its entirety) and has a low helix propensity (0.677) and low sheet propensity (0.766). Alternatively, proline could be substituted for glycine between motifs on the basis of calculated structure propensities. Additionally, a single tyrosine was included at the N-terminus of each peptide for concentration determination by UV absorption at 280 nm. SEQ ID NO:2 has a magnitude of the net charge of 20/32 (0.625) at pH 7; SEQ ID NO:1 has a magnitude of the net charge of 16/32 (0.5); SEQ ID NO:4 has a magnitude of the net charge of 30/48 (0.625) at pH 7; and SEQ ID NO:3 has a magnitude of the net charge of 24/48 (0.5) at pH 7. In all cases, the magnitude of the net charge is greater than or equal to approximately one-half of the total length of the first layer polypeptide at pH 7.

The polypeptides were named SN1 (SEQ ID NO: 2), SP2 (SEQ ID NO: 1), LN3 (SEQ ID NO: 4), and LP4 (SEQ ID NO: 3), respectively, meaning short negative, short positive, long negative, and long positive. These sequences are quite different from polylysine (commonly used in the art as a polycation) and polyglutamate (commonly used in the art as a polyanion) which, though available commercially and inexpensive, have a high α-helix propensity under conditions of mild pH and, crucially, are immunoreactive. The calculated charge per unit length on the designed peptides at neutral pH is 0.5 electrostatic units for SP and LP and 0.6 electrostatic units for SN and LN. The positive peptides are somewhat more hydrophobic than the negative ones, owing to the presence of valine and the long hydrocarbon side chain of arginine. (As mentioned above, hydrophobic interactions between polypeptide layers could stabilize films to some extent.) The lengths are consistent with published studies showing that polyions must have greater than 20 charged groups (i.e. aspartic acid and glutamic acid; lysine, arginine, and histidine) to be suitable for ELBL (see Kabanov, V. and Zezin, A. (1984) Pure Appl. Chem. 56:343 and Kabanov, V. (1994) Polym. Sci. 36:143, both of which are incorporated by reference herein in their entireties).

Experimental Demonstration Materials

QCM electrodes (USI-System, Japan) coated with evaporated silver had a surface area of 0.16±0.01 cm on each side, a resonant frequency of 9 MHz (AT-cut), and a long-term stability of ±2 Hz. The polypeptide molecular weight was verified by electrospray mass spectrometry. Peptide purity was greater than 70%. The polypeptide buffer was 10 mM sodium phosphate or 10 mM Tris-HCl, 1 mM DTT, 0.1 mM sodium azide, pH 7.4. All chemicals other than polypeptides were purchased from Sigma-Aldrich (USA).

Procedures

Experiments were done using pairs of designed polypeptides, one negative and one positive. Multilayer films consisting of at least 5 bi-layers of the above-identified SP2, SN1, LP4, and LN3 were deposited onto the QCM resonators using standard ELBL techniques (a bi-layer consists of one layer of polycation and one layer of polyanion). The polypeptide concentration used for layer adsorption was 2 mg-mL⁻¹. It is known that dependence of polyion layer thickness on polyelectrolyte concentration is not strong (see Lvov, Y. and Decher, G. (1994) Crystallog. Rep. 39:628, which is incorporated herein by reference in its entirety); in the concentration range 0.1 to 5 mg mL⁻¹, bilayer thickness was approximately independent of concentration for PSS/PAH. By contrast, polypeptide thin films appear substantially less thick than those fabricated using high molecular weight PSS/PAH (mass calculated using Δf data using the well-known Sauerbrey equation); see Lvov, Y. and Decher, G. (1994)Crystallog. Rep. 39:628. This follows from calculating film thickness on the basis of mass deposited, as is ordinarily done in the art for proteins. The calculated thickness for the designed polypeptide assembly shown in FIG. 3( c) is greater than the end-to-end length of the peptides used to make the film. DTT was included at 1 mM to inhibit disulfide bond formation. The adsorption time was 20 minutes.

Resonators were rinsed for 1 min. in pure water between subsequent adsorption cycles (removing perhaps 10-15% of weakly adsorbed material) and dried in a stream of gaseous N₂. Then the mass of the deposited peptide was measured indirectly by QCM. The mass measurement includes some water, despite drying, and low mass ions like K⁺, Na⁺, and Cl⁻. Partial interpenetration of neighboring layers of peptide is probable (see Decher, G. (1997) Science 227:1232; Schmitt et al. (1993) Macromolecules 26:7058; and Korneev et al. (1995) Physica B 214:954); this could be important for the efficiency of disulfide “locking.”

Results

After adsorption of the polypeptide and rinsing and drying the QCM resonator, the resonant frequency of the resonator was measured. This enabled calculation of the frequency shift on adsorption and change in adsorbed mass. A decrease in frequency indicates an increase in adsorbed mass. The results are provided in FIGS. 3( a) and 3(b). FIG. 3( a) shows a comparison of adsorption data for LP4 and LN3 in different buffers (10 mM sodium phosphate, pH 7.4, 1 mM DTT and 10 mM Tris-HCl, pH 7.4, 1 mM DTT). It is clear from these data that adsorption depends more on the properties of the peptides than the specific properties of the buffer used. FIG. 3( b) shows resonator frequency versus adsorbed layer for different combinations of SP2, SN1, LP4, and LN3 (namely, SP2/SN1, SP2/LN3, LP4/SN1, and LP4/LN3) in 10 mM sodium phosphate, pH 7.4 and 1 mM DTT (the lines merely connect experimental data points). Each of these combinations involved one negative polypeptide and one positive polypeptide, as required by ELBL. FIG. 3( c) shows a graph of calculated adsorbed mass versus layer number for SN1 and LP4 in 10 mM Tris-HCl, pH 7.4 and 1 mM DTT (calculated from experimental data using the Sauerbrey equation). The total adsorbed mass, approximately 5 μg, corresponds approximately to 1 nmol of peptide. The equation used for this calculation was Δm=−0.87·10⁻⁹ Δf, where m is mass in grams and f is frequency in Hz (see Lvov, Y., Ariga, K., Ichinose, I., and Kunitake, T. (1995) J. Am. Chem. Soc. 117:6117 and Sauerbrey, G. (1959) Z. Physik 155:206, both of which are incorporated herein by reference in their entireties). Film thickness, d, is estimated as d=−0.016Δf, where d is in nm (see Yuri Lvov, “Electrostatic Layer-by-Layer Assembly of Proteins and Polyions” in Protein Architecture: Interfacial Molecular Assembly and Immobilization Biotechnology, (Y. Lvov & H. Möhwald eds., 2000) (New York: Dekker, 2000) pp. 125-167, which is incorporated herein by reference). The line in FIG. 3( c) is a linear fit to experimental data points. The linearity of the data is a likely indicator of precise, regular assembly during adsorption and an approximately uniform density of the polypeptides in each adsorbed layer. Adsorption occurred with a frequency shift of −610±60 Hz (cations) or −380±40 Hz (anions). Linear growth of deposited polypeptide mass indicates repeatability of adsorption steps early in the assembly process and the general success of the multilayer fabrication process.

Conclusions

The above results show that polypeptides designed using the method of the present invention are suitable for ELBL, despite significant qualitative differences from PSS and PAH, flexible homopolymers having 1 charge per unit length at pH 7.4. The charge per unit length on poly-L-lysine and poly-L-glutamic acid is 1 at pH 7.4, as with PSS and PAH, but both of these polypeptides have a marked propensity to form α-helical structure under various conditions, making them substantially less suitable for multilayer assembly when control over thin film structure is desired. The monodisperse polypeptides of the present invention, however, enable the practitioner to know, quite precisely, the structure of the material being used for ELBL. Moreover, usual commercial preparations of poly-L-lysine and poly-L-glutamic acid are polydisperse, and poly-L-lysine, poly-L-glutamic acid, PSS, and PAH evoke an immune response (i.e. are immunogenic) in humans.

Because the designed polypeptides are readily adsorbed on an oppositely charged surface, as demonstrated by experiment, there is no need for a “precursor” layer. As is known in the art, “precursor” layers are deposited on a substrate to enhance adsorption of less adsorptive substances. The lack of a precursor layer enhances the biocompatibility of the polyion films because polymers ordinarily used as precursors are immunogenic or allow less precise control over polymer structure or thin film structure than designed polypeptides.

Multilayers of the designed polypeptides were stable at the pH of human blood, 7.4. Thus, the multilayers should be useful for a broad range of biological applications. Adsorption of the designed polypeptides, each of less than 1 charge per residue, was essentially complete in less than 10 min. at 2 mg/mL and low ionic strength. This implies that these polypeptides can be used to form multilayer films quickly and with relative ease. Drying the peptide film with N_(2(g)) after deposition of each layer did not impair assembly. Drying is done to get an accurate QCM frequency measurement, but is not required for assembly.

The film assembly experiments were done at a lower ionic strength than that of blood, but the process gives a qualitatively similar result at higher ionic strength. The chief difference is the amount of peptide deposited per adsorption layer—the higher the ionic strength, the greater the amount of peptide deposited. This is illustrated by the graph in FIG. 7, which shows the amount of material deposited as a function of ionic strength—the peptides used were poly-L-glutamic acid and poly-L-lysine. QCM resonant frequency is plotted against adsorption layer. The average molecular mass of poly-L-glutamate was 84,600 Da, while that of poly-lys was 84,000 Da. The peptide concentration used for assembly was 2 mg/mL. The data indicate salt concentration (ionic strength of solution) influences thin film assembly. In general, the amount of material deposited per layer increases with ionic strength in the range 0-100 mM NaCl. As the essential character of ELBL with designed polypeptides appears not to depend on the choice of buffer under conditions of relatively high net charge per unit length and low ionic strength, qualitatively similar results are expected at the ionic strength of human blood. Thus, the choice of buffer should not fundamentally alter the stability of the multilayers in their target environment. However, even if the choice of buffer did affect the stability of the multilayers, the “locking” mechanism would be available as a design feature to stabilize the capsule.

The greater apparent deposition of positive polypeptides than negative ones may result from the higher charge per unit length on the positive polypeptides at pH 7.4. The material deposited in each layer probably corresponds to that required for neutralization of the charge of the underlying surface. Hydrophobic interactions could also help to explain this feature of adsorption behavior.

The usual thin film thickness calculation for proteins and other polymers is probably invalid for short polypeptides (calculated thickness is 60-90 nm, but summed length of 10 polypeptides is approximately 120 nm). This probably results from a high density of packing of the relatively short polypeptides onto the adsorption surface; the result is also consistent with finding that film thickness varies with ionic strength, as changes in structural properties of a polymer will occur and screening of charges by ions will reduce intra-layer charge repulsion between adsorbed peptides. The thickness of the designed polypeptide thin film discussed here is estimated at 20-50 nm.

Many aspects of the design and fabrication cycles could be automated. For example, a computer algorithm could be used to optimize the primary structure of peptides for ELBL by comparing predicted peptide properties with observed physical properties, including structure in solution, adsorption behavior, and film stability at extremes of pH. Moreover, the polypeptide film assembly process can be mechanized, once the details of the various steps have been sufficiently determined.

Example 2 Experiments Involving De Novo-Designed Polypeptides Containing Cysteine Polypeptides

The polypeptides used were:

(SEQ ID NO: 5) Tyr Lys Cys Lys Gly Lys Val Lys Val Lys Cys Lys Gly Lys Val Lys Val Lys Cys Lys Gly Lys Val Lys Val Lys Cys Lys Gly Lys Val Lys (SEQ ID NO: 6) Tyr Glu Cys Glu Gly Glu Val Glu Val Glu Cys Glu Gly Glu Val Glu Val Glu Cys Glu Gly Glu Val Glu Val Glu Cys Glu Gly Glu Val Glu

Unlike the other polypeptides used in the experiments described herein, these two were not designed using human genome information; they were designed de novo for the sole purpose of assessing the role of disulfide bond formation in polypeptide film stabilization. SEQ ID NO:5 has a magnitude of the net charge of 16/32 (0.5) at pH 7; and SEQ ID NO:6 has a magnitude of the net charge of 16/32 (0.5) at pH 7. In both cases, the magnitude of the net charge is greater than or equal to approximately one-half of the total length of the first layer polypeptide at pH 7.

Procedures

All experiments were conducted at ambient temperature.

All assembly experiments using QCM were conducted in the same conditions, except that the samples to undergo oxidation were dried using air instead of nitrogen gas. The assembly conditions were 10 mM Tris-HCl, 10 mM DTT, pH 7.4. The nominal peptide concentration was 2 mg/mL. The number of layers formed was 14.

Disulfide locking conditions for the oxidizing samples were 10 mM Tris-HCl, 1% DMSO, saturation of water with air, pH 7.5. The duration of the “locking” step was 6 hours. Conditions for the reducing samples were 10 mM Tris-HCl, 1 mM DTT, saturation of water with nitrogen, pH 7.5. The duration of this step was 6 hours.

All disassembly experiments using QCM were conducted in the same conditions, except that the oxidizing samples were dried using air instead of nitrogen. Disassembly conditions were 10 mM KCl, pH 2.0 Samples were rinsed with D. I. water for 30 seconds prior to drying.

Three different types of experiments were conducted: (1) Reducing—no treatment: disassembly was conducted immediately after assembly; (2) Reducing—6 hours, as described above for reducing samples; and (3) Oxidizing—6 hours, as described above for oxidizing samples.

Results

The results are illustrated in FIG. 10. In the first two experiments (both reducing), all of the deposited material (100%) disassembled within 50 minutes. By contrast, in the oxidizing experiment, a substantial amount of material remained after substantial incubation of the peptide film-coated QCM resonator at pH 2 for over 5 hours. The stability of the polypeptide films at acidic pH is determined by the conditions of assembly; in this way, film or capsule stability is a design feature that becomes possible by using polypeptides as the polyelectrolytes for ELBL.

Conclusions

Electrostatic forces play a key role in holding together oppositely-charged layers of designed polypeptides. At acidic pH, the net charge on one of the peptides is neutralized and the polypeptide film disassembles due to electrostatic repulsion. Reducing conditions prevent disulfide bond formation. Therefore, the electrostatic attraction between the layers is the only binding force for stabilizing the layers under these conditions. By contrast, under oxidizing conditions disulfide bonds are formed. At acidic pH, disulfide bonds inhibit film disassembly. The results indicate that layer stability at acidic pH is directly affected by the formation of intra- and/or inter-layer disulfide bonds—i.e. between molecules in the same layer, between molecules in adjacent layers, or both. This is illustrated by the results shown in FIG. 10—due to disulfide locking, more than 30% of the film remained stable at acidic pH, despite electrostatic repulsion at relatively low ionic strength. Peptides with more cysteine residues are anticipated to further improve disulfide locking efficiency. Moreover, adjustment of the conditions of peptide assembly will be an important aspect of engineering films to have the desired physical as well as chemical and biological properties.

Example 3 Experiments Involving Designed Polypeptides Containing Cysteine Materials

The essential elements of this experiment were a quartz crystal microbalance instrument; silver-coated resonators (9 MHz resonant frequency); the negative 48-residue peptide (LN3) (SEQ ID NO: 4); and a positive 48-residue peptide named “SP5” of the following sequence:

(SEQ ID NO: 7) Tyr Lys Gly Lys Lys Ser Cys His Gly Lys Gly Lys Lys Ser Cys His Gly Lys Gly Lys Lys Ser Cys His Gly Lys Gly Lys Lys Ser Cys His

Like the other designed peptides discussed above in Part (D)(1), SP5 was designed using the process described above in Part (A)(1) to analyze the amino acid sequence of the human blood protein lactotransferrin (gi|4505043). The ELBL buffer was 10 mM Tris, pH 7.4, 10 mM NaCl, and 1 mM DTT. The disassembly buffer was 10 mM KCl, pH 2. 2 mL peptide solutions were prepared for SP5 and LN3 by adding 4 mg of each peptide to 2 mL of the above buffer solution and adjusting the pH of each solution to 7.4; the peptide concentration was 2 mg-mL⁻¹.

Procedure for Monitoring Assembly of Polypeptide Layers on QCM Resonators

Reducing procedures were as follows: (1) The frequency of the resonator was measured and recorded prior to peptide adsorption; (2) The resonator was dipped into the SP5 peptide solution for 20 min.; (3) The resonator was dipped into the SP5 rinse solution for 30 sec.; (4) The resonator was removed from the rinse solution and dried using nitrogen gas; (5) The QCM resonant frequency of the resonator was recorded; (6) The resonator was dipped into the LN3 peptide solution for 20 min.; (7) The resonator was dipped into the LN3 rinse solution for 30 sec.; (8) The resonator 1 was removed from the rinse solution and dried using nitrogen gas; (9) The QCM resonant frequency of the resonator was recorded; (10) Steps 2 through 9 were repeated until 16 layers were adsorbed onto the resonator.

Oxidizing procedures were the same as the reducing procedures, except that the resonator was rinsed in D. I. water instead of the SP5 buffer or the LN3 buffer and dried with air instead of nitrogen before each measurement.

Locking Procedures

Reducing procedures were as follows: The resonator was placed in an aqueous solution containing 1 mM DTT for 6 hours. DTT, a reducing agent, inhibited disulfide bond formation.

Oxidizing procedures were as follows: The resonator was placed in an air-saturated aqueous solution containing 1% DMSO for 6 hours. DMSO, an oxidizing agent, promoted disulfide bond formation.

Disassembly on Resonator: Solutions

Reducing conditions were as follows: 10 mM KCl, 1 mM DTT, pH 2.

Oxidizing conditions were as follows: 10 mM KCl, 20% DMSO, pH 2.

Procedure for Disassembly

Reducing procedures were as follows: (1) The initial resonant frequency of the resonator was measured by QCM and recorded; (2) The resonator was dipped into the reducing disassembly solution for 5 min.; (3) The resonator was rinsed in reducing buffer solution for 30 sec.; (4) The resonator was dried with gaseous N₂; (5) The resonant frequency of the resonator was measured by QCM and recorded; (6) Steps 2 through 5 were repeated for reading times of 5, 10, 15, 20, 30, 60, and 90 min.

Oxidizing procedures were the same as for reducing procedures, except that rinsing of the resonator was done in D. I. water saturated with air instead of reducing buffer.

Results

FIG. 8 shows approximately linear increase in mass deposited during thin film assembly of SP5 and LN3. Both resonators show almost identical deposition of mass throughout the process of assembly, despite differences in assembly conditions.

FIG. 9 shows the percentage of material remaining during film disassembly. The layers subjected to oxidizing conditions showed a minimal loss of material at acidic pH with almost 90 to 95% of mass retention. By contrast, layers subjected to reducing conditions lost almost all the film material within the first 5 minutes of exposure to acidic pH.

Conclusions

The results demonstrate that at acidic pH, disulfide bonds prevent layer degeneration and hold the layers firmly together. Layer stability at acidic pH is directly affected by the formation of intra- and/or inter-layer disulfide bonds. Disulfide bond formation is dependent on the concentration and proximity of cysteine residues to each other. Increasing the concentration per unit chain length of the polypeptide would therefore directly influence disulfide bond formation and thin film stability. Increasing the ionic strength of the buffer solutions used for film assembly influences the concentration of cysteine in the film by increasing the amount of material deposited per adsorption cycle and the thickness of each layer. The increased number of cysteine amino acids in a single layer would in this way increase the number of disulfide bonds formed, and, on oxidation, increase film stability.

Example 4

Films with polypeptides comprising an RGD functional domain wherein the magnitude of the linear charge density per residue is about 0.75.

In one embodiment, the functional region of a composite polypeptide is an RGD sequence wherein the charge density of the composite peptide is about 0.75. The RGD sequence binds the extracellular portion of the receptor protein integrin and thereby promotes cell adhesion. Sample peptide designs are the following:

KKKAKKKGKKKAKKKGRGDKKKAKKKGKKKAKKKY (SEQ ID NO:8) EEEAEEEGEEEAEEEGRGDEEEAEEEGEEEAEEEY (SEQ ID NO:9)

In this example, the polypeptide of SEQ ID NO:8 is a positively charged polypeptide having a functional region of RGD, a first surface adsorption region of KKKAKKKGKKKAKKKG (SEQ ID NO:10) and a second surface adsorption region of KKKAKKKGKKKAKKKY (SEQ ID NO:11). The magnitude of the net charge per residue at pH 7 of the composite peptide is + 26/35 or 0.74. The polypeptide of SEQ ID NO:9 is a negatively charged polypeptide having a functional region of RGD, a first surface adsorption region of EEEAEEEGEEEAEEEG (SEQ ID NO:12) and a second surface adsorption region of EEEAEEEGEEEAEEEY (SEQ ID NO:13). The magnitude of the net charge per residue at pH 7 of the composite peptide is − 26/35 or −0.74.

Various RGD sequence-containing peptides have been synthesized and their suitability for multilayer film assembly studied. The effect of the inclusion of RGD sequences in polypeptide multilayer films on the attachment and proliferation of different mammalian cell types has also been studied. Multilayer films comprising 5 bi-layers of (positive sequence) and (negative sequence) were deposited onto a quartz plate. The concentration of composite polypeptide for layer adsorption was 2 mg-mL⁻¹ in an aqueous solution at pH 7. The adsorption time was 20 min. Quartz plates were rinsed for 1 minute in pure water between subsequent adsorption cycles to remove weakly bound material. After deposition of each layer, the substrates for film assembly were dried in a stream of gaseous N₂. Then the optical mass of the deposited peptide was measured by UV spectroscopy. FIG. 16 compares the effect on cell proliferation of including RGD in peptides used to make the multilayer film. The technology is potentially useful for in vitro cell and tissue culture for the long-term purpose of regenerative medicine.

Example 5

Films with polypeptides comprising an RGD functional domain wherein the magnitude of the linear charge density per residue is about 0.4.

In one embodiment, the functional region of a composite polypeptide comprises an RGD sequence wherein the charge density of the composite peptide is ˜0.4. Sample peptide designs are the following:

AAKAKAKGKAKAKAKGRGDKAKAKAKGKAKAKAAY (SEQ ID NO:14) AAEAEAEGEAEAEAKGRGDKAEAEAEGEAEAEAAY (SEQ ID NO:15)

In this example, the polypeptide of SEQ ID NO:14 is a positively charged polypeptide having a functional region of RGD, a first surface adsorption region of AAKAKAKGKAKAKAKG (SEQ ID NO: 16) and a second surface adsorption region of KAKAKAKGKAKAKAAY (SEQ ID NO: 17). The magnitude of the net charge per residue at neutral pH of the composite peptide is + 14/35 or +0.4. The polypeptide of SEQ ID NO:15 is a negatively charged polypeptide having a functional region of RGD, a first surface adsorption region of AAEAEAEGEAEAEAEG (SEQ ID NO:18) and a second surface adsorption region of EAEAEAEGEAEAEAAY (SEQ ID NO:19). The magnitude of the net charge per residue at pH 7 of the composite peptide is − 14/35 or −0.4.

It is to be noted that the magnitude of the net charge per residue of a composite peptide can be determined by changing the structure of the surface adsorption region(s) or the functional region(s). In the present example, the net charge of the composite peptide of the previous example is changed by changing the structure of the surface adsorption regions only. In principle, it is possible to use the same approach to control the magnitude of the net charge per residue of any composite peptide. In this approach, however, both the surface adsorption region(s) and the functional region(s) should be independently soluble for the composite peptide to be soluble.

Example 6

Composite peptide wherein the functional region comprises two functional domains, wherein there is a surface adsorption region at the n-terminus of the functional region and at the c-terminus.

In this example, the functional domains are a Src homology 2 (SH2) domain, e.g., from human tensin, and a phosphotyrosine binding (PTB) domain, e.g., from human tensin. These domains bind specific proteins which are phosphorylated on tyrosine. An example of a composite peptide incorporating the indicated domains of human tensin is the following:

(SEQ ID No:20) KKKAKKKGKKKAKKKGKYWYKPEISREQAIALLKDQEPGAFIIRDSHSFR GAYGLAMKVSSPPPTIMQQNKKGDMTHELVRHFLIETGPRGVKLKGCPNE PNFGSLSALVYQHSIIPLALPCKLVIKYWYKPEISREQAIALLKDQEPGA FIIRDSHSFRGAYGLAMKVSSPPPTIMQQNKKGDMTHELVRHFLIETGPR GVKLKGCPNEPNFGSLSALVYQHSIIPLALPCKLVIKKKAKKKGKKKAKK KY

The surface adsorption regions are the same as in SEQ ID NO:10 and SEQ ID NO:11. The SH2 domain and the PTB domain sequences are available in accession NP_(—)072174 from the National Center for Biotechnology Information:

(SEQ ID NO:21) SH2 = KYWYKPEISR EQAIALLKDQ EPGAFIIRDS HSFRGAYGLA MKVSSPPPTI MQQNKKGDMT HELVRHFLIE TGPRGVKLKG CPNEPNFGSL SALVYQHSII PLALPCKLVI (SEQ ID NO:22) PTB = VLFVNSVDME SLTGPQAISK ATSETLAADP TPAATIVHFK VSAQGITLTD NQRKLFFRRH YPLNTVTFCD LDPQERKWMK TEGGAPAKLF GFVARKQGST TDNACHLFAE LDPNQPASAI VNFVSKVMLN AGQKR

We have synthesized a gene corresponding to the SH2 domain in human tensin and a gene corresponding to the PTB domain in human tensin, cloned the genes into a bacterial host, overexpressed the genes, purified the recombinant proteins, and characterized various physical properties of the domains. In one embodiment, multilayer films comprising 5 bi-layers of the indicated bioactive peptide and poly(L-glutamic acid) are deposited onto a silicon wafer for surface characterization and a quartz plate for monitoring of film assembly. The polypeptide concentration for layer adsorption is 2 mg-mL⁻¹ in an aqueous solution at pH 7. The adsorption time is 20 min. Substrates are rinsed for 1 min in water between subsequent adsorption cycles to remove weakly bound material. After deposition of each layer, substrates are dried in a stream of gaseous N₂. Then the optical mass of the deposited peptide on quartz is measured by UV spectroscopy, and the surface morphology of the film on a silicon wafer is characterized by atomic force microscopy. The technology is potentially useful for in vitro cell and tissue culture for the long-term purpose of regenerative medicine. Incorporation of the SH2 domain into a bioactive peptide as defined here enables a multilayer film to bind phosphotyrosinyl peptides. The technology is potentially useful for diagnostic purposes.

Example 7

Composite polypeptide comprising a single functional region and a single surface adsorption region at the n-terminus of the polypeptide.

In this example, the functional region is a known functional domain from a protein, e.g., the protein tyrosine phosphatase (PTP) domain of human auxilin:

(SEQ ID NO:23) KKKAKKKGKKKAKKKGLKDTLKDTSSRVIQSVTSYTKGDLDFTYVTSRII VMSFPLDNVDIGFRNQVDDIRSFLDSRHLDHYTVYNLSPKSYRTAKFHSR VSECSWPIRQAPSLHNLFAVCRNMYNWLLQNPKNVCVVHCLDGRAASSIL VGAMFIFCNLYSTPGPAIRLLYAKRPGIGLSPSHRYLGYMCDLLA

The surface adsorption region is the same as SEQ ID NO:10. The sequence of the PTP domain is available from the National Center for Biotechnology Information in accession 075061:

PTP Domain:

(SEQ ID NO:24) LKDTLKDTSSRVIQSVTSYTKGDLDFTYVTSRIIVMSFPLDNVDIGFRNQ VDDIRSFLDSRHLDHYTVYNLSPKSYRTAKFHSRVSECSWPIRQAPSLHN LFAVCRNMYNWLLQNPKNVCVVHCLDGRAASSILVGAMFIFCNLYSTPGP AIRLLYAKRPGIGLSPSHRRYLGYMCDLLA

Example 8

Composite polypeptide comprising two functional regions, wherein there are three surface adsorption regions, one at the N-terminus and one at the C-terminus of the composite peptide and one between the two functional regions, and wherein there are two different functional regions for glycosylation.

A representative peptide structure is the following:

-   -   SAR-functional region-SAR-functional region-SAR         where, as before, the SAR is a motif and therefore suitable for         surface adsorption, e.g., RRRARRR (SEQ ID NO:25), and one         functional region contains a recognition site for N-linked         glycosylation, e.g., GGNVSGG (SEQ ID NO:26), and the other for         O-linked glycosylation, e.g., PPSSSPP (SEQ ID NO:27). The amino         acid sequence of a representative composite peptide is:

RRRARRRGGNVSGGRRRARRRPPSSSPPRRRARRR (SEQ ID NO:28)

The magnitude of the net charge per residue at pH 7 of the composite polypeptide + 18/35≈+0.5. The multilayer film in this case is built of the indicated positive peptide and a suitable negative peptide, e.g.,

EEEAEEEGEEEAEEEGEEEAEEEGEEEAEEEY (SEQ ID NO:29)

Example 9

Composite peptide with one functional region, wherein there is one surface adsorption region at the C-terminus of the composite peptide, and wherein there is one functional region which comprises a peptide sequence known to have antimicrobial activity.

A representative peptide structure is the following:

-   -   Functional region-SAR         where, as before, SAR is a suitable surface adsorption region,         e.g., KKKAKKKGKKKAKKKY (SEQ ID NO:11), and the functional region         contains the sequence of histatin 5, viz.,         DSHAKRHHGYKRKFHEKHHSHRGY(SEQ ID NO: 30). The amino acid sequence         of a representative composite peptide is:

RRRARRRGGNVSGGRRRARRRPPSSSPPRRRARRR (SEQ ID NO:31)

The magnitude of the net charge at pH 5.5 per residue of the amino acid sequence of this representative composite peptide is + 24/39=+0.6. The multilayer film in this case is built of the indicated positive peptide and a suitable negative peptide, e.g., SEQ ID NO:29.

Example 10

Composite peptide with a single functional region, wherein there are two surface adsorption regions, one at the N-terminus and one at the C-terminus of the functional region, and wherein the functional region comprises two specific protease recognition sites and two linkers, each of which is a single glycine residue.

In one embodiment, the protease recognition sites are for enterokinase and thrombin:

SAR-enterokinase recognition-linker-thrombin recognition-linker-SAR

where in each instance SAR represents a suitable surface adsorption region, e.g., SEQ ID NO:10 and SEQ ID NO:11. The functional region is encoded, e.g., as DDDDKGLVPRGSG (SEQ ID NO:32), wherein DDDDK (SEQ ID NO: 33) is a recognition site for enterokinase, G is a linker, LVPRGS (SEQ id no: 34) is a recognition site for thrombin, and G is a linker. The amino acid sequence of a representative composite peptide is:

(SEQ ID NO:35) KKKAKKKGKKKAKKKGDDDDKGLVPRGSGKKKAKKKGKKKAKKKY

The magnitude of the net charge per residue at neutral pH of the composite peptide is + 22/46≈+0.5. The multilayer film in this case is built of the indicated positive peptide and a suitable negative peptide, e.g., SEQ ID NO:29.

Example 11

Composite peptide with two functional regions, wherein there are three surface adsorption regions, one at the N-terminus and one at the C-terminus of the composite peptide and one between the two functional regions, and wherein there are two identical functional regions for formation of natural peptide crosslinks.

A representative peptide structure is the following:

-   -   SAR-functional region-SAR-functional region-SAR         where, as before, SAR is a suitable surface adsorption region,         e.g., EEEAEEE (SEQ ID NO:36), and the functional region contains         a specific number of Cys residues, e.g., GGCGGCGG (SEQ ID         NO:37). The amino acid sequence of a representative composite         peptide is:

(SEQ ID NO:38) EEEAEEEGGCGGCGGEEEAEEEGGCGGCGGEEEAEEEY

The magnitude of the net charge per residue at pH 7 of the composite peptide is ˜0.5. The multilayer film in this case is built of the indicated negative peptide and a suitable positive peptide, e.g.,

KKKAKKKGKKKAKKKGKKKAKKKGKKKAKKKY (SEQ ID NO:39)

Example 12

Composite polypeptide comprising a single functional region and a single surface adsorption region at the C-terminus of the polypeptide.

In this example, the functional region is a known functional domain from a protein, e.g., the BAG domain of National Center for Biotechnology Information accession AAP06461:

BAG sequence-EEEAEEEGEEEAEEEY (SEQ ID NO:40) where “BAG sequence” represents the amino acid sequence of the BAG domain of a hypothetical protein from Schistosoma japonicum:

BAG sequence (SEQ ID NO:41) SLQPEIDRFDGTPHSKEFKCLMENLEQLILSLDNLETDGNVEFRTMRRDA VKEIQQLMEMLDYRSLISSQNDEVLAD

The surface adsorption region is the same as SEQ ID NO:13.

The use of the terms “a” and “an” and “the” and similar referents (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The terms first, second etc. as used herein are not meant to denote any particular ordering, but simply for convenience to denote a plurality of, for example, layers. The terms “comprising”, “having”, “including”, and “containing” are to be construed as open-ended terms (i.e., meaning “including, but not limited to”) unless otherwise noted. Recitation of ranges of values are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. The endpoints of all ranges are included within the range and independently combinable. All methods described herein can be performed in a suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (e.g., “such as”), is intended merely to better illustrate the invention and does not pose a limitation on the scope of the invention unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the invention as used herein.

Other embodiments of the invention are possible and modifications may be made without departing from the spirit and scope of the invention. Therefore, the detailed description above is not meant to limit the invention. Rather, the scope of the invention is defined by the appended claims. 

1. A multilayer film, comprising two or more layers of polyelectrolytes, wherein adjacent layers comprise oppositely charged polyelectrolytes, wherein a first layer polyelectrolye comprises a composite polypeptide comprising one or more non-homopolymer surface adsorption regions covalently linked to one or more functional regions forming a single polypeptide chain, wherein the composite polypeptide and the one or more non-homopolymer surface adsorption regions have the same polarity, wherein the one or more non-homopolymer surface adsorption regions comprises one or more amino acid sequence motifs, the one or more amino acid sequence motifs consisting of 5 to 15 amino acid residues and having a magnitude of net charge per residue at neutral pH of greater than or equal to 0.4, and wherein the one or more functional regions comprise 3 to about 250 amino acid residues, wherein the composite polypeptide is an unbranched polypeptide, is not a homopolymer, is at least 15 amino acid residues long, and has an aqueous solubility at pH 4 to 10 of greater than 50 μg/mL; wherein a second layer comprises a second layer polyelectrolyte comprising a polycationic material or a polyanionic material having a molecular weight of greater than 1,000 and at least 5 charges per molecule, and a charge opposite that of the first layer polypeptide.
 2. The multilayer film of claim 1, wherein the composite polypeptide has an aqueous solubility of greater than or equal to about 1 mg/mL.
 3. The multilayer film of claim 1, wherein the one or more functional regions comprise 3 to about 50 amino acid residues, and wherein the composite polypeptide has a magnitude of net charge per residue at neutral pH of greater than or equal to 0.4.
 4. The multilayer film of claim 1, wherein the one or more functional regions comprises about 50 to about 250 amino acid residues.
 5. The multilayer film of claim 4, wherein the one or more functional regions has a water solubility at pH 4 to 10 of greater than 50 μg/mL.
 6. The multilayer film of claim 5, wherein one or more the functional regions has a water solubility at pH 4 to 10 of greater than or equal to 1 mg/mL.
 7. The multilayer film of claim 4, wherein composite polypeptide comprises at least two amino acid sequence motifs.
 8. The multilayer film of claim 1, wherein the polycationic material comprises a polyamine.
 9. The multilayer film of claim 8, wherein the polyamine comprises polyvinyl amine, poly(aminostyrene), poly(aminoacrylate), poly (N-methyl aminoacrylate), poly (N-ethylaminoacrylate), poly(N,N-dimethyl aminoacrylate), poly(N,N-diethylaminoacrylate), poly(aminomethacrylate), poly(N-methyl amino-methacrylate), poly-(N-ethyl aminomethacrylate), poly(N,N-dimethyl aminomethacrylate), poly(N,N-diethyl aminomethacrylate), poly(ethyleneimine), poly (diallyl dimethylammonium chloride), poly(N,N,N-trimethylaminoacrylate chloride), poly(methyacrylamidopropyltrimethyl ammonium chloride), chitosan and combinations comprising one or more of the foregoing polycationic materials.
 10. The multilayer film of claim 1, wherein the polyanionic material comprises a nucleic acid, alginate, carrageenan, furcellaran, pectin, xanthan, hyaluronic acid, heparin, heparan sulfate, chondroitin sulfate, dermatan sulfate, dextran sulfate, poly(meth)acrylic acid, oxidized cellulose, carboxymethyl cellulose, acidic polysaccharides, and crosmarmelose, and combinations comprising one or more of the foregoing polyanionic materials.
 11. The multilayer film of claim 1, wherein the film is in the form of a microcapsule.
 12. The multilayer film of claim 1, wherein the film is formed on a substrate selected from an organic material and an inorganic material.
 13. The multilayer film of claim 12, wherein the substrate is a dissolvable template, calcium carbonate, melamine formaldehyde, or a polystyrene or styrene copolymer lattice.
 14. The multilayer film of claim 1, comprising at least 4 pairs of alternately charged layers.
 15. The multilayer film of claim 1, having a thickness of 1 nm to 100 nm.
 16. The multilayer film of claim 1, wherein the functional region is a T-cell epitope, B-cell epitope, or a cytotoxic T lymphocyte epitope.
 17. The multilayer film of claim 1, wherein at least one of the amino acid sequence motifs of the first layer polypeptide is present in the human proteome.
 18. A method of manufacturing a multilayer film, said film comprising a first layer and a second layer, wherein adjacent layers comprise oppositely charged polyelectrolytes, the method comprising: covalently joining one or more surface adsorption regions and one or more functional regions to form a composite polypeptide, wherein the composite polypeptide and the one or more surface adsorption regions have the same polarity, wherein the one or more surface adsorption regions comprises one or more amino acid sequence motifs consisting of 5 to 15 amino acid residues and having a magnitude of net charge per residue at neutral pH of greater than or equal to 0.4, and wherein the one or more functional regions comprises 3 to about 250 amino acid residues, wherein the composite polypeptide is not a homopolymer, is at least 15 amino acid residues long, and has an aqueous solubility in the range pH 4 to 10 of greater than 50 μg/mL; depositing the composite polypeptide onto a substrate or the second layer to form a first layer; and wherein the second layer comprises a second layer polyelectrolyte comprising a polycationic material or a polyanionic material having a molecular weight of greater than 1,000 and at least 5 charges per molecule, and a charge opposite that of the first layer polypeptide.
 19. The method of claim 18, wherein depositing comprises depositing the composite polypeptide onto a substrate, and further comprising depositing the second layer polyelectrolyte onto the first layer. 